The lathyrus toxin, β-N-oxalyl-l-α,β-diaminopropionic acid (ODAP), and homocysteic acid sensitize CA1 pyramidal neurons to cystine and l-2-amino-6-phosphonohexanoic acid

A brief exposure of hippocampal slices to L-quisqualic acid (QUIS) sensitizes CA1 pyramidal neurons 30- to 250-fold to depolarization by certain excitatory amino acids analogues, e.g., L-2-amino-6-phosphonohexanoic acid (L-AP6), and by the endogenous compound, L-cystine. This phenomenon has been termed QUIS sensitization. A mechanism similar to that previously described for QUIS neurotoxicity has been proposed to describe QUIS sensitization. Specifically, QUIS has been shown to be sequestered into GABAergic interneurons by the System x(c)(-) and subsequently released by heteroexchange with cystine or L-AP6, resulting in activation of non-NMDA receptors. We now report two additional neurotoxins, the Lathyrus excitotoxin, beta-N-oxalyl-L-alpha,beta-diaminopropionic acid (ODAP), and the endogenous compound, L-homocysteic acid (HCA), sensitize CA1 hippocampal neurons >50-fold to L-AP6 and >10-fold to cystine in a manner similar to QUIS. While the cystine- or L-AP6-mediated depolarization can be inhibited by the non-NMDA receptor antagonist CNQX in ODAP- or QUIS-sensitized slices, the NMDA antagonist D-AP5 inhibits depolarization by cystine or L-AP6 in HCA-sensitized slices. Thus, HCA is the first identified NMDA agonist that induces phosphonate or cystine sensitization. Like QUIS sensitization, the sensitization evoked by either ODAP or HCA can be reversed by a subsequent exposure to 2 mM alpha-aminoadipic acid. Finally, we have demonstrated that there is a correlation between the potency of inducers for triggering phosphonate or cystine sensitivity and their affinities for System x(c)(-) and either the non-NMDA or NMDA receptor. Thus, the results of this study support our previous model of QUIS sensitization and have important implications for the mechanisms of neurotoxicity, neurolathyrism and hyperhomocystinemia.

L-Quisqualic acid transport into hippocampal neurons by a cystine-sensitive carrier is required for the induction of quisqualate sensitization

A brief exposure of hippocampal slices to L-quisqualic acid sensitizes CA1 pyramidal neurons 30-250-fold to depolarization by two classes of excitatory amino acid analogues: (1) those whose depolarizing effects are rapidly terminated following washout, e.g. L-2-amino-4-phosphonobutanoic acid (L-AP4) and L-2-amino-6-phosphonohexanoic acid (L-AP6) and (2) those whose depolarizing effects persist following washout, e.g. L-aspartate-beta-hydroxamate (L-AbetaH). This process has been termed quisqualate sensitization. In this study we directly examine the role of amino acid transport systems in the induction of quisqualate sensitization. We report that L-quisqualate is a low-affinity substrate (K(M)=0.54 mM) for a high capacity (V(max)=0.9 nmol (mg protein)(-1) min(-1)) Na(+)-dependent transport system(s) and a high-affinity substrate (K(M)=0.033 mM) for a low-capacity (V(max)=0.051 nmol (mg protein)(-1) min(-1)) transporter with properties similar to the cystine/glutamate exchange carrier, System x(c-). We present evidence that suggests that System x(c-) participates in quisqualate sensitization. First, simultaneous application of L-quisqualate and inhibitors of System x(c-), but not inhibitors of Na(+)-dependent glutamate transporters, prevents the subsequent sensitization of hippocampal neurons to phosphonates or L-AbetaH. Second, L-quisqualic acid only sensitizes hippocampal neurons to other substrates of System x(c-), including cystine. Third, immunocytochemical analysis of L-quisqualate uptake demonstrates that only inhibitors of System x(c-) inhibit the highly concentrative uptake of L-quisqualate into a widely dispersed group of GABAergic hippocampal interneurons. We conclude that quisqualate sensitization is a direct consequence of the unique interaction of various excitatory amino acids, namely L-quisqualate, cystine, and phosphonates, with the exchange carrier, System x(c-). Therefore, the results of this study have important implications for the mechanism by which L-quisqualate, and other substrates of this transporter which are also excitatory amino acid agonists (such as glutamate and beta-N-oxalyl-L-alpha,beta-diaminopropionic acid, beta-L-ODAP) may trigger neurotoxicity.

Plague as a biological weapon: medical and public health management. Working Group on Civilian Biodefense

OBJECTIVE

The Working Group on Civilian Biodefense has developed consensus-based recommendations for measures to be taken by medical and public health professionals following the use of plague as a biological weapon against a civilian population.

PARTICIPANTS

The working group included 25 representatives from major academic medical centers and research, government, military, public health, and emergency management institutions and agencies.

EVIDENCE

MEDLINE databases were searched from January 1966 to June 1998 for the Medical Subject Headings plague, Yersinia pestis, biological weapon, biological terrorism, biological warfare, and biowarfare. Review of the bibliographies of the references identified by this search led to subsequent identification of relevant references published prior to 1966. In addition, participants identified other unpublished references and sources. Additional MEDLINE searches were conducted through January 2000.

CONSENSUS PROCESS

The first draft of the consensus statement was a synthesis of information obtained in the formal evidence-gathering process. The working group was convened to review drafts of the document in October 1998 and May 1999. The final statement incorporates all relevant evidence obtained by the literature search in conjunction with final consensus recommendations supported by all working group members.

CONCLUSIONS

An aerosolized plague weapon could cause fever, cough, chest pain, and hemoptysis with signs consistent with severe pneumonia 1 to 6 days after exposure. Rapid evolution of disease would occur in the 2 to 4 days after symptom onset and would lead to septic shock with high mortality without early treatment. Early treatment and prophylaxis with streptomycin or gentamicin or the tetracycline or fluoroquinolone classes of antimicrobials would be advised.

Cyclobutane quisqualic acid analogues as selective mGluR5a metabotropic glutamic acid receptor ligands

The conformationally constrained cyclobutane analogues of quisqualic acid (Z)- and (E)-1-amino-3-[2'-(3',5'-dioxo-1',2', 4'-oxadiazolidinyl)]cyclobutane-1-carboxylic acid, compounds 2 and 3, respectively, were synthesized. Both 2 and 3 stimulated phosphoinositide (PI) hydrolysis in the hippocampus with EC50 values of 18 +/- 6 and 53 +/- 19 microM, respectively. Neither analogue stimulated PI hydrolysis in the cerebellum. The effects of 2 and 3 were also examined in BHK cells which expressed either mGluR1a or mGluR5a receptors. Compounds 2 and 3 stimulated PI hydrolysis in cells expressing mGluR5a but not in those cells expressing mGluR1a. The EC50 value for 2 was 11 +/- 4 microM, while that for 3 was 49 +/- 25 microM. Both 2 and 3 did not show any significant effect on cells expressing the mGluR2 and mGluR4a receptors. In addition, neither compound blocked [3H]glutamic acid uptake into synaptosomal membranes, and neither compound was able to produce the QUIS effect as does quisqualic acid. This pharmacological profile indicates that 2 and 3 are selective ligands for the mGluR5a metabotropic glutamic acid receptor.

Persistent depression of synaptic responses occurs in quisqualate sensitized hippocampal slices after exposure to L-aspartate-beta-hydroxamate

Exposure of slices of rat hippocampus to quisqualic acid produces an enhanced sensitivity of neurons to depolarization by other excitatory amino acid analogues, particularly amino acid phosphonates. The phosphonates may act at extracellular sites, since their depolarizing effects are rapidly reversed by washout with phosphonate-free incubation medium. We now wish to report a novel class of excitatory amino acid analogues that induce a persistent depolarization that is not reversed by washout. Exposure of quisqualate-sensitized slices of rat hippocampus to 400 microM L-aspartate-beta-hydroxamate for 8 min results in the complete depression of extracellular synaptic field potentials. This depression persists for at least 1 h after washout of the hydroxamate compound. Analogous compounds L-glutamate-gamma-hydroxamate, D-aspartate-beta-hydroxamate and the phosphonate derivative L-2-amino-3-phosphonopropanoic acid (L-AP3) induce a similar but weaker persistent depression of the field potentials. Previous studies also demonstrated that exposure of hippocampal slices to L-alpha-aminoadipate blocks or reverses quisqualate sensitization, making the neurons unresponsive to depolarization by phosphonate compounds. We now report that L-alpha-aminoadipate also blocks or reverses the persistent depolarization of quisqualate-sensitized neurons which is induced by exposure to the hydroxamates or L-AP3.

A 3-amino-4-hydroxy-3-cyclobutene-1,2-dione-containing glutamate analogue exhibiting high affinity to excitatory amino acid receptors

The syntheses of several novel N-(hydroxydioxocyclobutenyl)-containing analogues of gamma-amino-butyric acid and L-glutamate were undertaken to test the hypothesis that derivatives of 3,4-dihydroxy-3-cyclobutene-1,2-dione (squaric acid), such as 3-amino-4-hydroxy-3-cyclobutene-1,2-dione, could serve as a replacement for the carboxylate moiety in neurochemically interesting molecules. The syntheses were successfully accomplished by preparation of a suitably protected diamine or diamino acid followed by reaction with diethyl squarate. Subsequent deprotection resulted in the isolation of the corresponding N-(hydroxydioxocyclobutenyl)-containing analogues 13, 14, and 18. These analogues were screened as displacers in various neurochemical binding site assays. The L-glutamate analogue 18, which showed high affinity as a displacer for kainate and AMPA binding, was also examined for agonist potency for CA1 pyramidal neurons of the rat hippocampal slice preparation. It rivaled AMPA as one of the most potent agonists for depolarizing pyramidal neurons in medium containing 2.4 mM Mg+2 ions in which kainate/AMPA receptors are active but NMDA receptors are inhibited (IC50 = 1.1 microM). It was 1 order of magnitude less potent for depolarizing pyramidal neurons under conditions in which kainate/AMPA receptors were inhibited by 10 microM CNQX but NMDA receptors were active in 0.1 mM Mg(+2)-containing medium (IC50 = 10 microM). Compound 18 did not induce sensitization of CA1 pyramidal cells to depolarization by phosphonate analogues of glutamate (the QUIS-effect).

Effects of quisqualic acid analogs on metabotropic glutamate receptors coupled to phosphoinositide hydrolysis in rat hippocampus

L-Glutamic acid (L-Glu) and L-aspartic acid (L-Asp) activate several receptor subtypes, including metabotropic Glu receptors coupled to phosphoinositide (PI) hydrolysis. Quisqualic acid (Quis) is the most potent agonist of these receptors. There is evidence that activation of these receptors may cause a long lasting sensitization of neurons to depolarization, a phenomenon called the Quis effect. The purpose of the current studies was to use Quis analogs and the recently identified metabotropic receptor antagonist, (+)-alpha-methyl-4-carboxy-phenylglycine((+)-MCPG), to define the structural properties required for interaction with the metabotropic receptors coupled to PI hydrolysis and to determine if the Quis effect is mediated by these receptors. The effects of Quis analogs on PI hydrolysis were studied in the absence or presence of the metabotropic receptor-specific agonist 1SR,3RS-1-amino-1,3-cyclopentanedicarboxylic acid (1SR,3RS-ACPD) in neonatal rat hippocampus. Some of the compounds that induce the Quis effect also stimulate PI hydrolysis, including Quis itself and 9 (homoquisqualic acid). Not all of the Quis analogs that stimulate PI hydrolysis, however, induce the Quis effect, including 7A (EC50 = 750 +/- 150 microM) and (RS)-4-bromohomoibotenic acid (BrHI) (EC50 = 130 +/- 40 microM). Although (+)-MCPG blocked PI hydrolysis stimulated by Quis (IC50 = 370 +/- 70 microM), it had no effect on the induction of the Quis effect. Other Quis analogs did not stimulate PI hydrolysis but rather blocked the effects of 1SR,3RS-ACPD. The IC50 values were 240 +/- 70 microM for 2, 250 +/- 90 microM for 3, and 640 +/- 200 microM for 4. Data for inhibition by 2 and 3 were consistent with non-competitive mechanisms of action. These studies provide new information about the structural features of Quis required for interaction with metabotropic receptors coupled to PI hydrolysis and provide evidence that the Quis effect is not mediated by (+)-MCPG sensitive subtypes of these receptors.

Type 4a metabotropic glutamate receptor: identification of new potent agonists and differentiation from the L-(+)-2-amino-4-phosphonobutanoic acid-sensitive receptor in the lateral perforant pathway in rats

Before the discovery of the metabotropic glutamate receptors (mGluRs), the glutamate analogue L-2-amino-4-phosphonobutanoic acid (L-AP4) was identified as a potent presynaptic inhibitor of evoked synaptic transmission in the lateral perforant pathway in rats. The localization and L-AP4 sensitivity of the mGluR4a subtype of mGluRs were consistent with the hypothesis that this receptor mediates the synaptic depressant effects of L-AP4 in the lateral perforant pathway. In the present study, the pharmacology of mGluR4a expressed in baby hamster kidney 570 cells was characterized and compared with that previously reported for the lateral perforant pathway responses. The endogenous excitatory amino acid L-aspartate was inactive at mGluR4a, whereas L-homocysteic acid was only 5-fold less potent than L-glutamate. These data suggest that L-homocysteic acid may be an endogenous agonist at mGluR4a. Of the 30 L-AP4 analogues examined, several compounds were identified as agonists at mGluR4a. The cyclopropyl-AP4 analogue (Z)-(+/-)-2-amino-2,3-methano-4-phosphonobutanoic acid inhibited forskolin-stimulated cAMP production with an EC50 of 0.58 microM, which is comparable to that of L-AP4 (EC50 = 0.43 microM). Two other cyclic analogues of L-AP4 were approximately 10-fold less potent as agonists at mGluR4a, i.e., (+/-)-1-amino-3-(phosphonomethylene)cyclobutanecarboxylic acid (EC50 = 4.4 microM) and (E)-(+/-)-2-amino-2,3-methano-4-phosphonobutanoic acid (EC50 = 7.9 microM). Comparison of the potencies of the compounds for activation of mGluR4a with their potencies for inhibition of lateral perforant pathway responses demonstrates that some compounds have comparable activities in the two systems, whereas several compounds are at least 10-fold more potent in one of the systems. In addition, although the mGluR antagonist (+)-alpha-methyl-4-carboxyphenylglycine blocked the effects of L-AP4 in the lateral perforant pathway, it did not block the effects of L-AP4 at the cloned receptor. These data provide evidence that mGluR4a does not mediate the effects of L-AP4 in the lateral perforant pathway, they provide new tools to identify the function of these receptors in the mammalian central nervous system, and they indicate that the effects of L-AP4 in the lateral perforant pathway are mediated by a (+)-alpha-methyl-4-carboxyphenylglycine-sensitive receptor.

Immunocytochemical evidence that quisqualate is selectively internalized into a subset of hippocampal neurons

Quisqualic acid (QUIS) has been shown to interact with several glutamate receptor subtypes and uptake sites. We have previously demonstrated that a brief exposure of hippocampal cells to QUIS sensitizes them to depolarization by the alpha-amino-omega-phosphonate analogues of glutamate, AP4, AP5, and AP6. This QUIS-induced sensitization is accompanied by the active uptake of QUIS into hippocampal slices. In order to localize the sites of QUIS uptake into rat hippocampal slices, a polyclonal antibody against QUIS was raised in rabbits. Utilizing immunocytochemical techniques, we have identified immunoreactive axons and dendrites after brief exposure times to QUIS, and perikarya after longer exposure times to QUIS. The intensity of the QUIS immunoreactivity increased as the exposure time to QUIS increased. QUIS immunoreactivity was primarily found in stratum oriens and stratum radiatum, of regions CA1, CA2, and CA3 of the hippocampus as well as in the hilus and molecular layer of the dentate gyrus. The distribution and morphology of QUIS immunoreactive cells appeared to be similar to those of GABAergic interneurons. Glial fibrillary acidic protein (GFAP) did not co-localize with the QUIS-internalizing cells suggesting that they are not glia. Ultrastructural analysis revealed QUIS immunoreactive profiles within the stratum radiatum. Immunostained profiles at both the light and EM levels appeared, in many cases, to be swollen and showed signs of degeneration. Such changes were only evident in tissue exposed to QUIS. These data demonstrate that QUIS is taken up by a select group of neurons in the rat hippocampus.

Synthesis of oxadiazolidinedione derivatives as quisqualic acid analogues and their evaluation at a quisqualate-sensitized site in the rat hippocampus

The ability of quisqualic acid (1) to sensitize neurons to depolarization by omega-phosphono alpha-amino acid analogues of excitatory amino acids is a highly specific phenomenon and is termed the QUIS effect. In an attempt to elucidate the structure-activity relationships for this sensitization, analogues 2-6 of quisqualic acid have been synthesized. Compounds 4, 5, and 6 showed no quisqualate sensitization with respect to L-2-amino-6-phosphonohexanoic acid (L-AP6), while compounds 2 and 3 were 1/10 and 1/1000, respectively, as active as quisqualic acid in sensitizing neurons toward L-AP6.

Utilization of the resolved L-isomer of 2-amino-6-phosphonohexanoic acid (L-AP6) as a selective agonist for a quisqualate-sensitized site in hippocampal CA1 pyramidal neurons

Brief exposure of rat hippocampal slices to quisqualic acid (QUIS) sensitizes neurons to depolarization by the alpha-amino-omega-phosphonate excitatory amino acid (EAA) analogues AP4, AP5 and AP6. These phosphonates interact with a novel QUIS-sensitized site. Whereas L-AP4 and D-AP5 cross-react with other EAA receptors, DL-AP6 has been shown to be relatively selective for the QUIS-sensitized site. This specificity of DL-AP6, in conjunction with the apparent preference of this site for L-isomers, suggested that the hitherto unavailable L-isomer of AP6 would be a potent and specific agonist. We report the resolution of the D- and L-enantiomers of AP6 by fractional crystallization of the L-lysine salt of DL-AP6. We also report the pharmacological responses of kainate/AMPA, NMDA, lateral perforant path L-AP4 receptors and the CA1 QUIS-sensitized site to D- and L-AP6, and compare these responses to the D- and L-isomers of AP3, AP4, AP5 and AP7. The D-isomers of AP4, AP5 and AP6 were 5-, 3- and 14-fold less potent for the QUIS-sensitized site than their respective L-isomers. While L-AP4 and L-AP5 cross-reacted with NMDA and L-AP4 receptors, L-AP6 was found to be highly potent and specific for the QUIS-sensitized site (IC50 = 40 microM). Its IC50 values for kainate/AMPA, NMDA and L-AP4 receptors were > 10, 3 and 0.8 mM, respectively. As with AP4 and AP5, sensitization to L-AP6 was reversed by L-alpha-aminoadipate.

Quisqualic acid induced sensitization and the active uptake of L-quisqualic acid by hippocampal slices

Hippocampal CA1 pyramidal cell neurons are sensitized to depolarization by L-2-amino-4-phosphonobutanoic acid (L-AP4) following exposure to L-quisqualic acid (QUIS). It has been proposed that induction of this 'QUIS-effect' involves uptake of L-QUIS by hippocampal cells. We have used o-phthaldialdehyde (OPA) derivatization and high performance liquid chromatographic (HPLC) separation of extracts from hippocampal slices which have been exposed to varied concentrations of L-QUIS to investigate L-QUIS uptake into hippocampal slices. We observe uptake rates such that the internal concentration of L-QUIS exceeds the bath concentration within 7 min. The fact that this uptake is concentrative indicates that it is mediated by an active transport system. In addition, uptake of L-QUIS may be linked to the induction of the QUIS-effect. At low concentrations of L-QUIS (< 4 microM), the QUIS-effect is only partially induced within the 4 min incubation time which maximally induces the effect when 16 microM L-QUIS is used. However, repeated 4 min exposure periods of slices to low L-QUIS concentrations will eventually induce the QUIS-effect even when each exposure is separated by extensive washout periods. Hence induction is dependent on both concentration and total exposure time. We also examined the effects of L-alpha-aminoadipic acid and L-serine-O-sulfate on the rate of L-QUIS uptake. Exposure of slices to these compounds prior to treatment with L-QUIS will block the physiological effects of L-QUIS. We found that these 'pre-blocking' compounds did not decrease the rate of L-QUIS uptake.(ABSTRACT TRUNCATED AT 250 WORDS)

Quisqualic acid analogues: synthesis of beta-heterocyclic 2-aminopropanoic acid derivatives and their activity at a novel quisqualate-sensitized site

Hippocampal CA1 pyramidal cell neurons are sensitized over 30-fold to depolarization by L-2-amino-4-phosphonobutanoic acid (L-AP4) following exposure to L-quisqualic acid. This phenomenon has been termed the QUIS effect. In the present study several novel L-quisqualic acid analogues have been synthesized and tested for their interaction with the different components of the QUIS-effect system. Replacement of the oxadiazolidinedione ring of L-quisqualic acid with several other types of heterocyclic rings yielded the following quisqualic acid analogues: maleimide 2, N-methylmaleimide 3, N-(carboxymethyl)maleimide 4, succinimides 5A and 5B, and imidazolidinedione 6. None of these analogues were able to mimic the effects of L-quisqualic acid and sensitize hippocampal CA1 neurons to depolarization by L-AP4. Also, unlike L-serine O-sulfate, L-homocysteinesulfinic acid, or L-alpha-aminoadipic acid, none of the analogues were able to preblock or reverse the QUIS effect. However, when the IC50 values for inhibition of the CA1 synaptic field potential of analogues 2-6 were determined both before and after hippocampal slices were exposed to L-quisqualic acid, the IC50 values of analogues 3 and 4 were found to decrease more than 7-fold. Thus, these two compounds behave like L-AP4 rather than L-quisqualic acid in this system in that they exhibit increased potencies in slices that have been pretreated with L-quisqualic acid even though they cannot themselves induce this sensitization. Compounds 3 and 4, therefore, represent the first non-phosphorus-containing compounds to which hippocampal neurons become sensitized following exposure to L-quisqualic acid. No change in the IC50 values was observed for 5A or 5B. Analogues 2 and 6, on the other hand, displayed a high potency for inhibition of the evoked field potential even prior to treatment of the slices with L-quisqualic acid.

Structure-function relationships for analogues of L-2-amino-4-phosphonobutanoic acid on the quisqualic acid-sensitive AP4 receptor of the rat hippocampus

Hippocampal CA1 pyramidal cell neurons are sensitized to depolarization by L-2-amino-4-phosphonobutanoic acid (L-AP4) following exposure to L-quisqualic acid (QUIS). We have examined the interaction of 43 structural analogues of L-AP4 with both the 'induction' site and the QUIS-sensitive AP4 site in rat hippocampus. The synthesis of cis- and trans-4-phosphonoxy-L-proline, 3-(RS)-amino-5-phosphonopentanoic acid and 2(RS)-amino-5-phenyl-4(RS)-phosphonopentanoic acid (gamma-benzyl AP4) are described. None of the test compounds interact with the induction site; thus L-QUIS remains the only compound known to induce this effect. However, one compound (L-2-amino-3-(5-tetrazolyl)-propanoic acid (L-aspartate tetrazole) 'pre-blocked' and reversed the effects of QUIS. In addition, the potency of 16 analogues increased more than 4-fold following exposure of slices to L-QUIS. Among these, L-AP4, L-AP5, 2-amino-4-(methylphosphino)butanoic acid (AMPB), and E-1(RS)-amino-3(RS)-phosphonocyclopentanecarboxylic acid (E-cyclopentyl AP4) displayed IC50 values of less than 0.100 mM after QUIS. The results presented here suggest that the QUIS-sensitive AP4 site requires a spatial configuration of functional groups similar to that present in E-cyclopentyl AP4. The presence of a primary amino group and a phosphorus-containing group (either monoanionic or dianionic) appear to be required, however, a carboxyl group is not essential for interaction. The pharmacology of the QUIS-sensitive AP4 site suggests that it is distinct from other known binding sites for L-AP4 in the central nervous system (CNS).

Activity of the conformationally rigid 2-amino-4-phosphonobutanoic acid (AP4) analogue (RS)-1-amino-3-(phosphonomethylene)cyclobutane-1-carboxylic acid (cyclobutylene AP5) on evoked responses in the perforant pathway of rat hippocampus

The highly rigid and conformationally extended 2-amino-4-phosphonobutanoic acid (AP4) analogue (RS)-1-amino-3-(phosphonomethylene)-cyclobutane-1-carboxylic acid (cyclobutylene AP5) was synthesized and found to inhibit evoked responses in the rat lateral perforant path (LPP) with an IC50 of 41 (+/- 1.5 S.E.M.) microM and the medial perforant pathway with an IC50 of 218 (+/- 3.7 S.E.M.) microM. Furthermore, paired pulse potentiation experiments suggest that cyclobutylene AP5 acts, in part, at a presynaptic site in the LPP. Thus, cyclobutylene AP5 appears to act in a similar manner to L-AP4 in the perforant pathway. These data support the hypothesis that L-AP4 assumes an extended conformation at the L-AP4 receptor of the LPP.

Characterization of retinal and hippocampal L-AP4 receptors using conformationally constrained AP4 analogues

In the past, the absence of useful 2-amino-4-phosphonobutanoic acid (AP4) analogues has hampered the pharmacological study and comparison of different systems which are sensitive to L-AP4. Several conformationally constrained AP4 analogues have now been synthesized: (E)- and (Z)-1-amino-3-phosphonocyclopentanecarboxylic acid [(E)- and (Z)-cyclopentyl AP4], and (E)- and (Z)-1-amino-3-phosphonocyclohexanecarboxylic acid [(E)- and (Z)-cyclohexyl AP4], and the recently synthesized cyclopropyl analogues (E)- and (Z)-2-amino-2,3-methano-4-phosphonobutanoic acid [(E)- and (Z)-cyclopropyl AP4]. Therefore, we have examined and report here the pharmacology of two retinal and two hippocampal L-AP4 sensitive systems using these analogues. In addition, the pharmacology of two kainic acid/alpha-amino-3-hydroxy-5-methylisoxazole-4- propionic acid (KAIN/AMPA) pathways and one N-methyl-D-aspartate (NMDA) hippocampal pathway was examined. We found that the rank order potency of the L-AP4 sensitive systems were similar though not identical. The KAIN/AMPA and NMDA systems had a quite different rank order of potencies than the L-AP4 systems. These data suggest that the L-AP4 receptors in these different systems are structurally similar to each other and differ from both KAIN/AMPA and NMDA receptors.

NMDA-, kainate- and quisqualate-stimulated release of taurine from electrophysiologically monitored rat hippocampal slices

While excitatory amino acids (EAAs) are known to evoke the release of taurine in the hippocampus, we have found that taurine is localized primarily in dendrites and only to a lesser extent in terminals in this region. To determine whether taurine is released as a neurotransmitter by non-toxic concentrations of EAAs, or exclusively as a neuroprotectant in response to excitotoxicity, we monitored the release of amino acids from hippocampal slices during simultaneous electrophysiological recording in the CA1 region to assess tissue viability. N-methyl-D-aspartate (NMDA) was the most potent of the EAA agonists tested for stimulating release of taurine. Exposure of slices to 120 microM NMDA increased the concentration of taurine in the perfusate to 1325% of its basal value. Kainate (KA) at a concentration of 128 microM increased taurine to 543% of baseline while quisqualate (Quis) at a concentration of 120 microM increase taurine to only 202% of its baseline value. Release of taurine in response to NMDA and KA peaked during the period when the concentration of the agonist was declining in the bath and did not return to its baseline value until 20 min after removal of the agonist. Increases in release of taurine were associated with concentrations of NMDA, KA, and Quis that caused an incomplete recovery of the CA1 field potential. These results suggest that taurine is primarily released by concentrations of glutamate receptor agonists that exhibit evidence of excitotoxicity in the CA1 region.

Synthesis of the 2-amino-4-phosphonobutanoic acid analogues (E)- and (Z)-2-amino-2,3-methano-4-phosphonobutanoic acid and their evaluation as inhibitors of hippocampal excitatory neurotransmission

The cyclopropyl compounds (Z)- and (E)-2-amino-2,3-methano-4-phosphonobutanoic acid, 5 and 6, respectively, were prepared as constrained analogues of 2-amino-4-phosphonobutanoic acid (AP4), a selective glutamate receptor ligand. A Horner-Emmons reaction of trimethyl N-(benzyloxycarbonyl)phosphonoglycinate with 2-(diethoxyphosphinyl)acetaldehyde gave the protected dehydroamino acids 9 and 10, which were individually subjected to the following sequence of reactions: cycloaddition of diazomethane, photoelimination of N2, and acid hydrolysis, to give 5 and 6, respectively. Extracellular recording techniques were used to evaluate the abilities of 5 and 6 to block evoked synaptic transmission in specific neuronal pathways of the rat hippocampal slice. In the lateral perforant path (LPP) 5 and 6 were equipotent and possessed IC50 values of 18 and 17 microM, respectively. In the medial perforant path (MPP), 6 (IC50 = 81 microM) was much more potent than 5 (IC50 = 1580 microM). In paired pulse experiments which differentiate presynaptic and postsynaptic inhibition, 5 and 6 enhanced the second response to the same extent as L-AP4, suggesting a presynaptic site of action for these compounds. In contrast, the cyclopentyl AP4 analogues 3 and 4 enhanced the second response to a lesser extent. It was concluded that the biologically active conformation of AP4 in the LPP is different than in the MPP. In order to explain the same potency of 5 and 6 in the LPP, it was postulated that the two analogues assume a conformation that allows their functional groups to occupy the same relative place in space. Molecular modeling showed that the best overlap was achieved when the alpha C-beta C-gamma C-P dihedral angle for 5 was in the range of 130 degrees to 180 degrees and that of 6 was in the range of -130 degrees to -180 degrees. The results suggest that the bioactive conformation of AP4 in the LPP is an extended one.

Pre-exposure to L-homocysteinesulfinic acid blocks quisqualate-induced sensitization to L-2-amino-4-phosphonobutanoic acid

Quisqualic acid sensitizes hippocampal CA1 neurons to depolarization by L-2-amino-4-phosphonobutanoic acid (L-AP4). This sensitization to L-AP4 is known to be blocked by simultaneous exposure to L-homocysteinesulfinic acid, L-alpha-aminoadipic acid and L-serine-O-sulfate during exposure to quisqualate. We report here that these compounds also act as 'pre-blockers' which, when added and removed from the medium prior to exposure to quisqualate, prevent subsequent induction of sensitization to L-AP4 by quisqualate. This pre-blockade suggests that simple competitive inhibition of extracellular receptor or uptake sites may not be the mechanism by which these compounds attenuate the action of quisqualate in this 'Quis-effect'.

Synthesis of acyclic and dehydroaspartic acid analogues of Ac-Asp-Glu-OH and their inhibition of rat brain N-acetylated alpha-linked acidic dipeptidase (NAALA dipeptidase)

The following structural and conformationally constrained analogues of Ac-Asp-Glu-OH (1) were synthesized: Ac-Glu-Glu-OH (2), Ac-D-Asp-Glu-OH (3), Ac-Glu-Asp-OH (4), Ac-Asp-Asp-OH (5), Ac-Asp-3-aminohexanedioic acid (6), Ac-3-amino-3-(carboxymethyl)propanoyl-Glu-OH (7), N-succinyl-Glu-OH (8), N-maleyl-Glu-OH (9), N-fumaryl-Glu-OH (10), and Ac-delta ZAsp-Glu-OH (11). These analogues were evaluated for their ability to inhibit the hydrolysis of Ac-Asp-[3,4-3H]-Glu-OH by N-acetylated alpha-linked acidic dipeptidase (NAALA dipeptidase) in order to gain some insight into the structural requirements for the inhibition of this enzyme. Analogues 4-6 and 9 were very weak inhibitors of NAALA dipeptidase (Ki greater than 40 microM), while 2, 3, and 7 with Ki values ranging from 3.2-8.5 microM showed intermediate inhibitory activity. The most active inhibitors of NAALA dipeptidase were compounds 8, 10, and 11 with Ki values of 0.9, 0.4, and 1.4 microM, respectively. These results suggest that the relative spacing between the side chain carboxyl and the alpha-carboxyl group of the C-terminal residue may be important for binding to the active site of the enzyme. They also indicate that the chi 1 torsional angle for the aspartyl residue is in the vicinity of 0 degrees.

An explanation for the purported excitation of piriform cortical neurons by N-acetyl-L-aspartyl-L-glutamic acid (NAAG)

The excitation of piriform cortical neurons by iontophoresis of N-acetyl-L-aspartyl-L-glutamic acid (NAAG) isolated from rat brain is frequently cited as major support for the possible neurotransmitter role of NAAG in the CNS [ffrench-Mullen, J. M. H., Koller, K., Zaczek, R., Coyle, J. T., Hori, N. & Carpenter, D. O. (1985) Proc. Natl. Acad. Sci. USA 82, 3897-3900]. However, we have been unable to reproduce this observation using synthetic NAAG, and instead we offer an alternative explanation. In our experiments, iontophoresis of the sodium salt of synthetic NAAG did not induce single-unit spiking at sites in slices of rat piriform cortex that responded vigorously to L-glutamate. In contrast, iontophoresis of the potassium salt of synthetic NAAG or of potassium ions alone induced single unit activity. The responses to both NAAG/KCl and KCl alone were inhibited by L-2-amino-4-phosphonobutanoic acid and desensitized rapidly, as previously reported for NAAG. These results suggest that residual potassium ions, remaining after the original purification of NAAG, were responsible for the excitations attributed to NAAG.

High-affinity transport of L-glutamine by a plasma membrane preparation from rat brain

Plasma membrane vesicles prepared from rat brain contain a saturable, high-affinity transport system for L-glutamine that exhibits the following characteristics: (1) The rate of L-glutamine transport is linear up to 200 micrograms/mL membrane protein. (2) Transport of [3H]-L-glutamine is linear with time for at least 10 min, is significantly reduced by lowering the assay temperature to 4 degrees C, and is essentially abolished by the addition of excess unlabeled L-glutamine. (3) The transport rate is optimal in the range of pH 7.4-8.2. (4) The system exhibits a Km for L-glutamine of approximately 1.7 microM and a Vmax of approximately 46 pmol/(min.mg of protein). (5) The system is not highly dependent upon the addition of monovalent or divalent cations. (6) Inhibitor studies reveal that the amino acid amides exhibit the highest affinity for the system and that there is a high specificity for the L-isomers.

Novel recognition site for L-quisqualate sensitizes neurons to depolarization by L-2-amino-4-phosphonobutanoate (L-AP4)

Brief exposure of rat hippocampal slices to L-quisqualate sensitizes pyramidal neurons to depolarization by L-2-amino-4-phosphonobutanoate (L-AP4). We report here experiments designed to clarify the duration, pharmacology, mechanism, and pathway specificity of this 'QUIS-effect'. The quisqualate-induced sensitization to L-AP4 decreases only 3-fold over a 4 h period. No compound besides quisqualate has been found to induce the QUIS-effect, including quisqualate analogues, potent excitatory amino acid agonists, L-glutamate, L-aspartate, and compounds known to stimulate second messenger systems in hippocampal slices. Of 43 compounds assayed here, only 5 are able to block the induction of the QUIS-effect. Although these blockers are also potent ligands at a chloride-dependent glutamate uptake site, the marked difference in rank ordering of compounds for QUIS-effect blockade and uptake site potency suggests that the QUIS-effect is not induced through this uptake site. The QUIS-effect can be induced in the CA1 region, the medial perforant path, and the lateral olfactory tract of the rat, and in the guinea pig CA1. It cannot be induced in the L-AP4-sensitive rat lateral perforant path (LPP), suggesting that the receptors for L-AP4 in the LPP may be distinct from those that are sensitized by quisqualate in the other pathways.

Cyclic analogues of 2-amino-4-phosphonobutanoic acid (APB) and their inhibition of hippocampal excitatory transmission and displacement of [3H]APB binding

Conformationally restricted analogues of 2-amino-4-phosphonobutanoic acid (APB,2) were prepared where the structure of APB was incorporated into cyclopentane (3) or cyclohexane (4) rings. Hydrophosphinylation of the appropriate cycloalkenones followed by Strecker amino acid syntheses provided the desired analogues. Assignments of the relative configurations for 3a (trans), 3b (cis), 4a (cis), and 4b (trans) were determined through 13C NMR studies. Compounds 3b, 4a, and 4b possessed low activity as inhibitors of excitatory synaptic field potentials in the rat hippocampal perforant path. Analogues 4a and 4b also showed little activity in displacing [3H]APB from synaptic plasma membranes. The cyclopentyl APB analogue 36, on the other hand, was extremely potent in inhibiting the binding of [3H]APB, possessing an IC50 = 4.7 microM, thus giving further credence to the idea that the APB binding site in the rat brain synaptosomal membrane preparation is not the same as the receptor mediating APB-induced inhibition of the lateral perforant path. Of the four cyclic APB analogues, 3a most resembled APB in its spectrum of biological activity. It showed significant potency (IC50 = 130 microM) in inhibiting lateral entorhinal projections to hippocampal granule cells. Analogous to APB, 3a also showed selectivity for the lateral perforant path over the medial perforant path. Its activity in the radioligand binding assay paralleled its activity in inhibiting the lateral perforant path. It thus appears that 3a comes closest to mimicking the active conformation of APB and suggests that a folded conformation wherein the amino and phosphonate moieties are in a cis relationship to one another may approximate the active conformation of APB.

Exposure of hippocampal slices to quisqualate sensitizes synaptic responses to phosphonate-containing analogues of glutamate

Exposure of transverse slices of rat hippocampus to quisqualate (Quis) resulted in a marked increase in the potency of D- and L-2-amino-4-phosphonobutanoate (APB) and D- and L-2-amino-5-phosphonopentanoate (APV) for depression of extracellular synaptic field potentials recorded from CA1 pyramidal cells. L-APB depressed the amplitude of CA1 field potentials with an IC50 = 1800 microM before exposure to Quis. After a brief (4 min) exposure to sufficient Quis (16 microM) to depress the response by 50%, L-APB depressed these responses with an IC50 = 54 microM. These phosphonate-containing glutamate analogues transiently induced population-spiking after the tissue was pretreated with Quis. This suggests that APB and APV can act as agonists at micromolar concentrations.

Structure-function relationships for kynurenic acid analogues at excitatory pathways in the rat hippocampal slice

Eight kynurenic acid analogues were bath-applied to rat hippocampal slices while recording extracellular synaptic field potentials and the potencies of these analogues for inhibition of these responses were compared to that of kynurenic acid. Quinaldic acid, 4-hydroxyquinoline, 4-hydroxypicolinic acid, L-kynurenine and picolinic acid inhibited evoked field potentials, but were at least 15-fold less potent than kynurenic acid in all pathways tested. Xanthurenic acid was inactive in the pathways tested. Quinolinic acid and dipicolinic acid showed signs of agonist activity with IC50's of approx. 400 microM and 2500 microM, respectively. These studies show that the 2-carboxy group and the 4-hydroxy moiety are essential for the antagonist activity exhibited by kynurenate. They also show that the unsubstituted second aromatic ring greatly enhances the affinity of kynurenate for these receptors and that substitution in at least one position on this aromatic ring abolishes activity.

Displacement of DL-[3H]-2-amino-4-phosphonobutanoic acid ( [3H]APB) binding with methyl-substituted APB analogues and glutamate agonists

The binding of the excitatory amino acid antagonist DL-2-amino-4-phosphonobutanoic acid (DL-APB) to rat brain synaptic plasma membranes was characterized. As determined by Scatchard analysis, the binding was saturable and homogeneous with a Kd = 6.0 microM and Bmax = 380 pmol/mg of protein. The binding was dependent on the presence of Ca2+ and Cl- ions and was diminished upon freezing. The association rate constant was 6.8 X 10(-3) microM-1 min-1, and the dissociation rate constant was 2.0 X 10(-2) min-1. The L isomers of APB, glutamate, and aspartate were more potent as displacers of APB binding than the D isomers. Previously determined inhibition data obtained for APB-sensitive inputs to hippocampal granule cells are compared to the present displacement data in an attempt to identify this binding protein as the recognition site of the receptor mediating the APB-induced inhibition of synaptic transmission. With the exception of kynurenic acid, all compounds examined in both systems were more potent as displacers of APB binding than as inhibitors of synaptic transmission. This difference in potency was most pronounced for agonists at dentate granule cells. L-Glutamate, D-glutamate, and L-glutamate tetrazole were between 140- and 7500-fold more potent as displacers of DL-APB binding than as inhibitors of synaptic transmission. D-2-Amino-5-phosphonopentanoic acid and alpha-methyl-APB were between 10- and 20-fold more potent as displacers of binding.(ABSTRACT TRUNCATED AT 250 WORDS)

Antagonist activity of methyl-substituted analogues of 2-amino-4-phosphonobutanoic acid in the hippocampal slice

Four monomethyl-substituted analogues of 2-amino-4-phosphonobutanoic acid (APB), an antagonist of excitatory pathways in the central nervous system, were prepared in order to investigate the steric requirements of the APB receptor. Methyl groups were incorporated at the amino, alpha-, beta-, and gamma-positions. The beta- and gamma-methyl-substituted analogues of APB were found to be moderately potent antagonists in excitatory synapses of the hippocampal perforant path, as judged by extracellular recording techniques, while the N- and alpha-methyl-substituted analogues had much lower potencies. All of these APB analogues had very low potencies in the Schaffer collateral pathway. The APB receptors in the perforant path displayed more tolerance of methyl-substitution at the beta- and gamma-positions of APB than at the amino or alpha-positions in this system.

Kynurenic acid as an antagonist of hippocampal excitatory transmission

Kynurenate, an endogenous tryptophan metabolite, was bath-applied to hippocampal slices while recording extracellular synaptic field potentials. Kynurenate antagonized the medial and lateral entorhinal projections to dentate granule cells, the Schaffer collateral projections to CA1 pyramidal cells, and inputs to the CA3 stratum radiatum of regio inferior with similar potencies. Concentration-response curves for these pathways paralleled theoretical antagonist curves with a Hill coefficient of 1, and the KdS were in the range of 130-400 microM. Projections to the stratum lucidum of regio inferior were much less sensitive to kynurenate. Inputs to CA3 pyramidal cells showed varying sensitivities to kynurenate, L-2-amino-4-phosphonobutanoic acid (L-APB), and (-)-baclofen depending on the placements of the stimulating and recording electrodes. When both electrodes were located in area CA3, outside the hilus of area dentata, all responses were insensitive to inhibition by L-APB. Under these conditions, responses recorded within the stratum radiatum were sensitive to inhibition by kynurenate and baclofen, while responses recorded within the stratum lucidum were insensitive to these drugs. When the stimulating electrode was placed within the hilus of area dentata, variable patterns of sensitivity to APB, baclofen, and kynurenate were observed from recording electrodes in area CA3. These results suggest that stimulation in the hilus, while recording in the stratum lucidum, produces responses that show composite effects resulting both from direct stimulation of mossy fibers and from stimulation of neuronal elements in the hilus which produce outputs to mossy fibers.

Antagonist activity of phosphorus-containing glutamate analogues in the perforant path

Two analogues of the amino acid L-2-amino-4-phosphonobutanoic acid (L-APB) were synthesized in order to test the hypothesis that the dianionic nature of the side chain is responsible for antagonism of excitatory synapses in the hippocampal perforant path. These compounds, DL-2-amino-4-(methylphosphino)-butanoic acid (DL-AMPB) and O-methylphosphonyl-L-serine (O-MPLS), possess singly-charged side chains and yet display antagonistic activity, illustrating that a dianionic charge on the side chain is not necessary for antagonism. Comparing structure-activity relationships for DL-AMPB, O-MPLS, L-APB, and O-phospho-L-serine (O-PLS), patterns of synaptic activity emerged which suggest that substitution of a methyl group for one of the phosphoryl hydroxyl groups lowers ligand potency in both medial and lateral pathways. Also, the nature of the atom at the gamma-position appears to alter the potency and degree of pathway selectivity of these ligands, a methylene unit imparting more potency and selectivity than an oxygen atom.

Structure - function relationships for gamma-substituted glutamate analogues on dentate granule cells

We previously demonstrated in the Schaffer collateral-CA1 region of the hippocampus that bath-applied agonists could be distinguished from antagonists among a group of acidic amino acid analogues by extracellular recording techniques. Here we report the use of the extracellular signs of agonist activity for discerning agonists and antagonists among several gamma-substituted glutamate analogues tested in the perforant path. The two-pathway composition of the perforant path offers the advantage over CA1 in that pathway-specificity, a postulated characteristic of antagonists, may be tested. By extracellular recording, D- and L-homocysteic acid, L-serine-O-sulfate, and L-2-amino-4-(5-tetrazolyl)-butanoic acid [L-glutamate tetrazole] were identified as agonists, and all 4 analogues were more potent than L-glutamate for inhibiting synaptic field potentials. Two previously identified antagonists, L-2-amino-4-phosphonobutyric acid and L-O-phosphoserine, exhibited the pathway-specificity and inhibitory kinetics consistent with properties expected for antagonists; both compounds detected 3 perforant path components with the same rank in sensitivity, suggesting that they are acting on the same set of receptors.

A microperfusion chamber for brain slice pharmacology

The construction of a chamber for extracellular recording from submerged CNS tissue is described. Its operation is illustrated using hippocampal slices prepared from rat brains. The total volume of perfusing medium is less than 0.4 ml, and a drug solution can be uniformly distributed throughout this volume in less than 1 min. Drug-laden medium can also be rapidly replaced with fresh medium. The perfusing medium is continuously stirred with a jet of 95% O2-5% CO2, maintaining submerged slices viable for many hours. The system has exceptional advantages for investigating synaptic pharmacology of scarce and expensive drugs.

Response of Schaffer collateral-CA 1 pyramidal cell synapses of the hippocampus to analogues of acidic amino acids

Analogues of the putative excitatory transmitters aspartic acid and glutamic acid were tested for antagonism against stimulus-evoked activation of Schaffer collateral-CA 1 pyramidal cell synapses in slices of rat hippocampus. Responses to the analogues, applied via the superfusing medium, were extracellularly recorded. The compounds examined included D- and L-alpha-aminodicarboxylic acids, diaminodicarboxylic acids, phosphonate analogues of acidic amino acids, D- and L-gamma-glutamyl glycine, and the cis- and trans-isomers of piperidine 2,3-, and 2,4-dicarboxylic acid. Many of these compounds are known to be potent and selective antagonists for excitatory amino acids and a few excitatory pathways. In this hippocampal pathway most of these analogues showed relatively low and similar potency. The most potent antagonist uncontaminated with agonist activity was D-alpha-aminosuberate, with an apparent antagonist dissociation constant (Kd) of 3 mM. Only 5 of the analogues, 3 of the piperidine dicarboxylates, kainic acid, and L-alpha-aminopimelic acid, reduced the amplitude of the extracellularly recorded field potentials more than 30% at 0.5 mM. However, all of the others reduced the potential by more than 30% at 5 mM. Most analogues also evoked extracellular responses which can be attributed to depolarization of the pyramidal neurons. Agonist activity was particularly strong among the most potent analogues. These results contrast with the responses documented by others for the N-methyl-D-aspartate receptor of the dorsal-ventral root excitatory pathway of the spinal cord in which the higher homologues tested here were the most potent antagonists, and the D-isomers were more potent than the L-isomers. It also contrasts with the response of the perforant path synapses to granule cells of the dentate gyrus in which the portion derived from the lateral entorhinal cortex is sensitive to L-2-amino-4-phosphonobutyric acid. Thus the Schaffer-CA 1 pyramidal cell synaptic field utilizes a novel excitatory transmitter receptor which interacts detectably but only weakly with a variety of acidic amino acids with potent specific inhibitory action for receptors elsewhere in the central nervous system.

Micromolar L-2-amino-4-phosphonobutyric acid selectively inhibits perforant path synapses from lateral entorhinal cortex

Transverse slices of the rat hippocampus were used to examine the ability of phosphonate analogues of acidic amino acids to inhibit perforant path synaptic transmission. Micromolar concentrations of L-2-amino-4-phosphonobutyric acid (APB), an analogue of L-glutamic acid, inhibited transmission from the lateral entorhinal cortex. Two other less-sensitive components were detected in projections from the medial entorhinal cortex. The component from the lateral entorhinal cortex showed high stereospecificity for the L-isomer of APB and was relatively insensitive to phosphonate homologues of shorter and longer chain length.

Protein induced by bacteriophage T4 which is absent in Escherichia coli infected with nuclear disruption-deficient phage mutants

A protein induced by wild-type T4 phage which is absent in Escherichia coli infected with nuclear disruption-deficient phage (with mutations in gene ndd) was identified by polacrylamide gel electrophoresis. This protein was synthesized at maximum rate at 3 to 6 min after infection. It had a molecular weight of 15,000 determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. It was associated with sedimentable fractions of the cell from which it can be dissociated with 1 M guanidine-hydrochloride. The dissociated protein can be partly recovered in a form soluble in dilute buffer after partial purification and dialysis. The occurrence of this protein in a particulate cell fraction is of interest because of the postulated role of the bacterial cell membrane in nuclear disruption.

Shutoff of host macromolecular synthesis after T-even bacteriophage infection

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Identification and preliminary characterization of a mutant defective in the bacteriophage T4-induced unfolding of the Escherichia coli nucleoid

The nucleoids of Escherichia coli S/6/5 cells are rapidly unfolded at about 3 min after infection with wild-type T4 bacteriophage or with nuclear disruption deficient, host DNA degradation-deficient multiple mutants of phage T4. Unfolding does not occur after infection with T4 phage ghosts. Experiments using chloramphenicol to inhibit protein synthesis indicate that the T4-induced unfolding of the E. coli chromosomes is dependent on the presence of one or more protein synthesized between 2 and 3 min after infection. A mutant of phage T4 has been isolated which fails to induce this early unfolding of the host nucleoids. This mutant has been termed "unfoldase deficient" (unf-) despite the fact that the function of the gene product defective in this strain is not yet known. Mapping experiments indicate that the unf- mutation is located near gene 63 between genes 31 and 63. The folded genomes of E. coli S/6/5 cells remain essentially intact (2,000-3,000S) at 5 min after infection with unfoldase-, nuclear disruption-, and host DNA degradation-deficient T4 phage. Nuclear disruption occurs normally after infection with unfoldase- and host DNA degradation-deficient but nuclear disruption-proficient (ndd+), T4 phage. The host chromosomes remain partially folded (1,200-1,800S) at 5 min after infection with the unfoldase single mutant unf39 x 5 or an unfoldase- and host DNA degradation-deficient, but nuclear disruption-proficient, T4 strain. The presence of the unfoldase mutation causes a slight delay in host DNA degradation in the presence of nuclear disruption but has no effect on the rate of host DNA degradation in the absence of nuclear disruption. Its presence in nuclear disruption- and host DNA degradation-deficient multiple mutants does not alter the shutoff to host DNA or protein synthesis.

Unfolding of the host genome after infection of Escherichia coli with bacteriophage T4

The folded genome of Escherichia coli is converted to a slower-sedimenting form within 5 min after infection with bacteriophage T4 or T4nd28(den A)-amN82(44). Chloramphenicol sensitivity and response to UV-irradiation of the phage suggest participation of viral-induced functions.

Identification and genetic characterization of mutants of bacteriophage T4 defective in the ability to induce exonuclease A

A mutant of bacteriophage T4 unable to induce exonuclease A has been isolated. The mutation responsible for this defect maps between genes 39 and 56, in a region of the chromosome devoid of other known markers. Four deletion mutants lacking part of the genome located between genes 39 and 56 also fail to induce exonuclease A. The ability of all of these mutants to replicate suggests that exonuclease A is not essential for replication of phage T4.

Isolation of bacteriophage T4 mutants defective in the ability to degrade host deoxyribonucleic acid

A method was devised for identifying nonlethal mutants of T4 bacteriophage which lack the capacity to induce degradation of the deoxyribonucleic acid (DNA) of their host, Escherichia coli. If a culture is infected in a medium containing hydroxyurea (HU), a compound that blocks de novo deoxyribonucleotide biosynthesis by interacting with ribonucleotide reductase, mutant phage that cannot establish the alternate pathway of deoxyribonucleotide production from bacterial DNA will fail to produce progeny. The progeny of 100 phages that survived heavy mutagenesis with hydroxylamine were tested for their ability to multiply in the presence of HU. Four of the cultures lacked this capacity. Cells infected with one of these mutants, designated T4nd28, accumulated double-stranded fragments of host DNA with a molecular weight of approximately 2 x 10(8) daltons. This mutant failed to induce T4 endonuclease II, an enzyme known to produce single-strand breaks in double-stranded cytosine-containing DNA. The properties of nd28 give strong support to an earlier suggestion that T4 endonuclease II participates in host DNA degradation. The nd28 mutation mapped between T4 genes 32 and 63 and was very close to the latter gene. It is, thus, in the region of the T4 map that is occupied by genes for a number of other enzymes, including deoxycytidylate deaminase, thymidylate synthetase, dihydrofolate reductase, and ribonucleotide reductase, that are nonessential to phage production in rich media.