Endogenous reverse transcriptase assays reveal synergy between combinations of the M184V and other drug resistance-conferring mutations in interactions with nucleoside analog triphosphates

Resistance of HIV-1 reverse transcriptase (RT) to nucleoside analogs (e.g. AZT, ddC and 3TC) is conferred by various amino acid substitutions or combinations thereof on the RT molecule. The M184V mutation, that confers high and low-level resistance to 3TC and ddC, respectively, can restore sensitivity to AZT when introduced into RT against a background of AZT-resistance. The K65R mutation, that confers low level resistance to both 3TC and ddC, can also restore sensitivity to AZT. This information is of potential utility in choosing combinations of anti-viral drugs for clinical use. To explore this subject further, we have used an endogenous RT reaction to study mutated viruses containing M184V alone or M184V combined with each of the K65R, E89G or both the M41L and T215Y substitutions. Endogenous assays possess the advantage of utilizing genomic RNA as template in a reaction mixture that includes each of tRNALys.3 and viral nucleocapsid protein, necessary for specific initiation of reverse transcription, as well as all other viral proteins that might impact on this process. We now show that viruses containing both M184V and K65R displayed synergistic resistance to 3TC triphosphate (3TCTP), while the same combination yielded the same level of resistance to ddC triphosphate (ddCTP) as that manifested by K65R alone. The combination of M184V and E89G displayed synergistic resistance against ddCTP but not 3TCTP, while viruses containing only E89G were highly resistant to 3TCTP and displayed low-level resistance to ddCTP. The results show that endogenous RT assays can reveal variable synergistic, antagonistic, or neutral effects in regard to drug sensitivity, depending on the presence of specific amino acid substitutions in RT itself.

Sequence elements downstream of the human immunodeficiency virus type 1 long terminal repeat are required for efficient viral gene transcription

We investigated the role of a 54-nucleotide region (+200 to +253) located downstream of the HIV-1 long terminal repeat (LTR) on virus gene expression and found, using RT-PCR and p24 CA analysis, that deletion of this region inhibited synthesis of both viral RNA and protein. CAT assays showed that these results were attributable to decreased transcription efficiency of the HIV-1 LTR and not to the stability of the RNA transcripts produced. Further deletional analysis and transfection studies showed that the most important sequences with regard to proviral DNA expression were located between nucleotide positions +218 and +237. Furthermore, substitutional mutational analysis showed that a CTCTCTC sequence at positions +227 to +233, homologous to the pyrimidine-rich initiator (Inr) region found in several promoters, was required for efficient production of both viral RNA and protein. Deletion of the sequence +200 to +217, homologous to the interferon-stimulated response element (ISRE), resulted in impaired LTR promoter activity and decreased synthesis of viral RNA and protein. However, when the latter region was replaced by homologous ISRE sequences from an interferon-stimulated gene (ISG-54), an even more severe effect on HIV gene expression and replication was observed, suggesting that ISRE-like sequences in HIV act differently from homologous sequences in interferon-responsive cellular genes.

The alpha chain of laminin-1 is independently secreted and drives secretion of its beta- and gamma-chain partners

A mammalian recombinant strategy was established to dissect rules of basement membrane laminin assembly and secretion. The alpha-, beta-, and gamma-chain subunits of laminin-1 were expressed in all combinations, transiently and/or stably, in a near-null background. In the absence of its normal partners, the alpha chain was secreted as intact protein and protein that had been cleaved in the coiled-coil domain. In contrast, the beta and gamma chains, expressed separately or together, remained intracellular with formation of betabeta or betagamma, but not gammagamma, disulfide-linked dimers. Secretion of the beta and gamma chains required simultaneous expression of all three chains and their assembly into alphabetagamma heterotrimers. Epitope-tagged recombinant alpha subunit and recombinant laminin were affinity-purified from the conditioned medium of alphagamma and alphabetagamma clones. Rotary-shadow electron microscopy revealed that the free alpha subunit is a linear structure containing N-terminal and included globules with a foreshortened long arm, while the trimeric species has the typical four-arm morphology of native laminin. We conclude that the alpha chain can be delivered to the extracellular environment as a single subunit, whereas the beta and gamma chains cannot, and that the alpha chain drives the secretion of the trimeric molecule. Such an alpha-chain-dependent mechanism could allow for the regulation of laminin export into a nascent basement membrane, and might serve an important role in controlling basement membrane formation.

Identification of sequences downstream of the primer binding site that are important for efficient replication of human immunodeficiency virus type 1

Reverse transcription of retroviruses is initiated from an 18-nucleotide (nt) primer binding site (PBS), located within the 5' region of viral genomic RNA, to which the host cell-derived tRNA primer is annealed and also involves viral genomic sequences outside the PBS. We constructed proviral DNA clones of human immunodeficiency virus (HIV) that had selective deletions of either a 7-nt segment found immediately downstream of the PBS or an extended nontranslated 54-nt stretch located immediately downstream of the PBS and containing the aforementioned 7-nt segment. Synthesis of minus-strand strong-stop DNA was assessed with MT-4 cells infected with viruses derived from COS-7 cells that had been transfected with these various constructs. We found that similar levels of minus-strand strong-stop DNA as well as DNA produced after template switching were expressed in MT-4 cells infected with COS-7-derived wild-type viruses or with viruses that had the 7-nt segment deleted. In contrast, significantly lower levels of viral DNA were detected in MT-4 cells after infection with viruses that had deletions of the 54-nt stretch. Furthermore, the molecular clone containing the 7-nt deletion was able to replicate with wild-type kinetics, while that containing the 54-nt deletion displayed a significantly diminished capacity in this regard. Further deletion analysis showed that a 16-nt segment at the 3' end of this 54-nt segment was largely responsible for these effects. We also conducted studies to determine levels of viral mRNA in COS-7 cells that had been transfected with equivalent amounts of DNA derived from either a wild-type HIV construct or our various deletion mutants. In the case of transfections performed with the 7-nt deletion mutant and wild-type HIV DNA, high levels of viral mRNA transcripts were detected, which was not the case for the 54 nt-deletion mutant. However, these various mRNAs possessed similar stabilities, as shown through studies in which transcript formation was arrested by treatment of cells with actinomycin D. Thus, the 54-nt segment of 5' nontranslated RNA, located downstream of the PBS, is involved in efficient expression of each of viral DNA, mRNA, and infectious virus.

The importance of the A-rich loop in human immunodeficiency virus type 1 reverse transcription and infectivity

Nucleotide segment (+169)AAAA(+172) constitutes an A-rich loop within human immunodeficiency virus type 1 (HIV-1) (HXB2D) RNA and is able to interact with the anticodon loop (33)/USUU(36) of primer tRNA3(Lys). We have shown that the deletion of this A-rich loop resulted in diminished levels of infectivity and reduced synthesis of viral DNA in MT-2 cells and cord blood mononuclear cells. Endogenous reverse transcriptase (RT) assays revealed that the mutated viruses, termed HIV/del-A, generated fewer cDNA products than did wild-type virus, designated HIV/WT. We also employed in vitro RT assays with in vitro-synthesized viral RNA templates, recombinant HIV-1 RT(p66/51), and natural tRNA3(Lys) as primers to show that the mutated RNA templates, designated PBS/del-A, generated less minus-strand strong-stop DNA product than did the wild-type RNA template, designated PBS/WT. The initiation efficiency of reverse transcription from the mutated RNA template was significantly impaired compared with that from the wild-type RNA template when a single-base extension assay from the tRNA3(Lys) primer was employed. However, RT reactions performed with DNA oligonucleotides complementary to the primer binding site (PBS) as primers did not yield differences between the mutated PBS/del-A and wild-type RNA templates. Long-term culture of HIV/del-A in MT-2 cells resulted in the replacement of two G's at nucleotide positions 167 and 168 by two A's that possessed the same relationship to the 5' end of the PBS as did the wild-type A's at positions 171 and 172. In vitro RT assays performed with recombinant enzyme with tRNA3(Lys) as the primer showed that the RNA template thus generated, termed PBS/A2, yielded levels of minus-strand strong-stop DNA product similar to those yielded by the wild-type RNA template. Coincidentally, viruses containing A's at positions 167 and 168 were able to replicate with efficiencies similar to those of the wild-type viruses. Thus, the (+169)AAAA(+172) A-rich loop plays a key role in the synthesis of viral DNA.

Controlling elements in replication of the human immunodeficiency virus type 1

We have reviewed the genetic structure of HIV-1 from the perspective of understanding viral and cellular regulatory factors that affect viral replication. Comparisons are drawn, as appropriate, with other human retroviruses, such as HIV-2, in regard to our understanding of pathogenesis. The synthesis of viral protein and the manner in which viral assembly takes place is also discussed.

Endogenous reverse transcription assays reveal high-level resistance to the triphosphate of (-)2'-dideoxy-3'-thiacytidine by mutated M184V human immunodeficiency virus type 1

Kinetic analysis showed that the Ki values and the Ki/Km ratios for mutated, recombinant M184V human immunodeficiency virus type 1 reverse transcriptase (RT) for (-)2'-dideoxy-3'-thiacytidine triphosphate (3TCTP) were 35-fold higher than the equivalent values for wild-type RT but only about twice as high as the equivalent values for each of the triphosphates of ddC (ddCTP) and ddA (ddATP). Fully endogenous RT assays showed that viruses containing the M184V substitution were highly resistant to 3TCTP, with an increase in the 50% inhibitory concentration of 250-fold in comparison with wild-type recombinant virus.

Human immunodeficiency virus Type 1 nucleocapsid protein (NCp7) directs specific initiation of minus-strand DNA synthesis primed by human tRNA(Lys3) in vitro: studies of viral RNA molecules mutated in regions that flank the primer binding site

Retroviral reverse transcription starts near the 5' end of unspliced viral RNA at a sequence called the primer binding site (PBS), where the tRNA primer anneals to the RNA template for initiation of DNA synthesis. We have investigated the roles of NCp7 in annealing of primer tRNA(Lys3) to the PBS and in reverse transcriptase (RT) activity, using a cell-free reverse transcription reaction mixture consisting of various 5' viral RNA templates, natural primer tRNA(Lys3) or synthetic primer, human immunodeficiency virus type I (HIV-1) nucleocapsid protein (NCp7), and HIV-1 RT. In the presence of tRNA(Lys3), NCp7 was found to stimulate synthesis of minus-strand strong-stop DNA [(-)ssDNA], consistent with previous reports. However, specific DNA synthesis was observed only at a NCp7/RNA ratio similar to that predicted to be present in virions. Moreover, at these concentrations, NCp7 inhibited the synthesis of nonspecific reverse-transcribed DNA products, which are initiated because of self-priming by RNA templates. In contrast to results obtained with tRNA(Lys3) as primer, NCp7 inhibited the synthesis of (-)ssDNA products primed by an 18-nucleotide (nt) ribonucleotide (rPR), complementary to the PBS, even though rPR can initiate synthesis of such material in the absence of preannealing with NCp7. Primer placement band shift assays showed that NCp7 was necessary for efficient formation of the tRNA-RNA complex. In contrast, NCp7 was found to prevent formation of the rPR-RNA complex. Since NCp7 appears to exert opposite effects (annealing versus dissociation) on tRNA(Lys3) and rPR substrates, the non-PBS binding regions of the tRNA(Lys3) molecule may play a role in the annealing of tRNA to the template. We also investigated the roles of an A-rich loop upstream of the PBS, a 7-nt region immediately downstream of the PBS, and a 54-nt deletion further downstream of the PBS in interactions with tRNA(Lys3). We found that deletions in the 54-nt region that may prevent formation of the U5-leader stem prevented tRNA(Lys3) placement and priming, while deletions in the A-rich loop or the 7-nt sequence had relatively minor effects in this regard.

Studies of neutralizing monoclonal antibody to human immunodeficiency virus type 1 reverse transcriptase: antagonistic and synergistic effects in reactions performed in the presence of nucleoside and nonnucleoside inhibitors, respectively

We have assessed interactions between the reverse transcriptase (RT) of human immunodeficiency virus type 1 (HIV-1) and a neutralizing monoclonal antibody (1E8) that hinders binding of deoxynucleoside triphosphate (dNTP) substrates. Steady-state reactions with homopolymeric template-primers revealed that 1E8 antagonized inhibition of RT activity mediated by 3'-azido-3'-deoxythymidine triphosphate and 2',3'-dideoxycytidine triphosphate. However, an additive or synergistic inhibition of RT polymerase activity was noted when 1E8 and the nonnucleoside RT inhibitors nevirapine and delavirdine were studied. Chain elongation and dNTP incorporation studies using an HIV-1 genome-derived heteropolymeric template and either oligodeoxynucleotide or tRNA3(Lys) as the primer yielded results consistent with the above observations. 1E8 also increased pausing at certain sites during synthesis of negative-strand, strong-stop DNA, whether or not ddNTP and nonnucleoside RT inhibitors were present.

Effects of non-nucleoside inhibitors of human immunodeficiency virus type 1 in cell-free recombinant reverse transcriptase assays

We have employed a cell-free human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) assay to study the effects of non-nucleoside inhibitors of RT (NNRTI) by directly monitoring specific HIV DNA products using a HIV-1 genome-derived template and an oligodeoxynucleotide primer. As previously shown by ourselves and others, nucleoside analog triphosphates, e.g. 3'-azido-3'-deoxythymidine triphosphate and 2',3'-dideoxyadenosine triphosphate, could directly inhibit HIV RT RNA-dependent DNA polymerase activity by causing chain termination, as visualized in a RT reaction that yields specific DNA products. In contrast, each of two NNRTIs, nevirapine and delavirdine, directly inhibited RT activity without causing chain termination effects. We also analyzed interactions between nucleoside analogs and NNRTIs or among NNRTIs by chain elongation/dNTP incorporation and/or steady-state kinetic assays. Combinations of nevirapine with the triphosphates of either the (-)-strand of 2',3'-dideoxy-3'-thiacytidine or 2',3'-dideoxyadenosine yielded additive/synergistic effects on RT activity. However, only an additive effect was observed when combinations of nevirapine and 3'-azido-3'-deoxythymidine triphosphate were employed. Combinations of nevirapine and delavirdine had an antagonistic effect on the inhibition of HIV-1 RT activity.

Identification and characterization of a sequence motif involved in nonsense-mediated mRNA decay

In both prokaryotes and eukaryotes, nonsense mutations in a gene can enhance the decay rate or reduce the abundance of the mRNA transcribed from that gene, and we call this process nonsense-mediated mRNA decay. We have been investigating the cis-acting sequences involved in this decay pathway. Previous experiments have demonstrated that, in addition to a nonsense codon, specific sequences 3' of a nonsense mutation, which have been defined as downstream elements, are required for mRNA destabilization. The results presented here identify a sequence motif (TGYYGATGYYYYY, where Y stands for either T or C) that can predict regions in genes that, when positioned 3' of a nonsense codon, promote rapid decay of its mRNA. Sequences harboring two copies of the motif from five regions in the PGK1, ADE3, and HIS4 genes were able to function as downstream elements. In addition, four copies of this motif can function as an independent downstream element. The sequences flanking the motif played a more significant role in modulating its activity when fewer copies of the sequence motif were present. Our results indicate the sequences 5' of the motif can modulate its activity by maintaining a certain distance between the sequence motif and the termination codon. We also suggest that the sequences 3' of the motif modulate the activity of the downstream element by forming RNA secondary structures. Consistent with this view, a stem-loop structure positioned 3' of the sequence motif can enhance the activity of the downstream element. This sequence motif is one of the few elements that have been identified that can predict regions in genes that can be involved in mRNA turnover. The role of these sequences in mRNA decay is discussed.

Characterization of cis-acting sequences and decay intermediates involved in nonsense-mediated mRNA turnover

Several lines of evidence indicate that the processes of mRNA turnover and translation are intimately linked and that understanding this relationship is critical to elucidating the mechanism of mRNA decay. One clear example of this relationship is the observation that nonsense mutations can accelerate the decay of mRNAs in a process that we term nonsense-mediated mRNA decay. The experiments described here demonstrate that in the yeast Saccharomyces cerevisiae premature translational termination within the initial two-thirds of the PGK1 coding region accelerates decay of that transcript regardless of which of the stop codons is used. Nonsense mutations within the last quarter of the coding region have no effect on PGK1 mRNA decay. The sequences required for nonsense-mediated mRNA decay include a termination codon and specific sequences 3' to the nonsense mutation. Translation of two-thirds of the PGK1 coding region inactivates the nonsense-mediated mRNA decay pathway. This observation explains why carboxyl-terminal nonsense mutations are resistant to accelerated decay. Characterization of the decay of nonsense-containing HIS4 transcripts yielded results mirroring those described above, suggesting that the sequence requirements described for the PGK1 transcript are likely to be a general characteristic of this decay pathway. In addition, an analysis of the decay intermediates of nonsense-containing mRNAs indicates that nonsense-mediated mRNA decay flows through a pathway similar to that described for a class of wild-type transcripts. The initial cleavage event occurs near the 5' terminus of the nonsense-containing transcript and is followed by 5'-->3' exonucleolytic digestion. A model for nonsense-mediated mRNA decay based on these results is discussed.

Antiquity of Homo sapiens in China

Ten years ago a well-preserved skull of an early form of Homo sapiens was unearthed from Pleistocene cave deposits at the Jinniushan site in China. Here we present electron-spin resonance (ESR) and uranium-series dates from five fossil animal teeth collected from the hominid locality. The minimum ESR ages (195-165 kyr) are about 50 kyr younger than the uranium-series dates. Taken together, the results suggest an age of about 200 kyr or older for the Jinniushan skull, making it among the oldest H. sapiens material found in China, and almost as old as some of the latest Chinese H. erectus. This raises the possibility of the coexistence of the two species in China. The morphology of the skull suggests a strong local component of evolution, consonant with the 'multi-regional continuity' model of the evolution of H. sapiens.

[Widespread tau abnormality in a case of cortico-basal degeneration]

A case with cortico-basal degeneration was reported with special reference to the immunohistochemical study. A 59-year-old housewife noted tremor and clumsiness of her left hand. On the initial examination she showed the hyperreflexia of the upper extremities and jaw jerk, parkinsonian symptoms such as Myerson sign, parkinsonian gait and rigidity in the left arm. She showed pronounced forced grasping in the left hand. At the age of 60 she showed a WAIS scale with verbal IQ of 99 and performance below the scale. She could not copy hand postures. Tremor was aggravated by action or anxiety, more prominent on the left hand. There was some incoordination on the finger-nose testing of left arm and on the knee-heel testing of both legs. She also showed homolateral dyskinesia. She had a left Babinski sign and sensory testing was normal. A CT scan showed slightly enlarged ventricles (Fig. 1). At the age of 61 she could not understand simple requests and speak few words spontaneously, showing severe dysarthria. There were palilalia and motor impersistence. CT scan showed more widening of the lateral ventricles. At the age of 62, she had lingual dyskinesia and tapping on her upper lip provoked myoclonic jerk on her arms. She died of pneumonia at the age of 65 years, 6 years from the onset. The brain weighed 1190 g. There were bilateral old subdural hematomas on the right parietal and occipital lobe and the left parietal lobe. There was atrophy of frontal and superior parietal region.(ABSTRACT TRUNCATED AT 250 WORDS)