The sequence of 3'-termini of mRNAs from early region III of adenovirus 2

The complete nucleotide sequence of the egg drop syndrome virus: an intermediate between mastadenoviruses and aviadenoviruses

The complete nucleotide sequence of an avian adenovirus, the egg drop syndrome (EDS) virus, was determined. The total genome length is 33,213 nucleotides, resulting in a molecular weight of 21.9 x 10(6). The GC content is only 42.5%. Between map units 3.5 and 76.9, the distribution of open reading frames with homology to known genes is similar to that reported for other mammalian and avian adenoviruses. However, no homologies to adenovirus genes such as E1A, pIX, pV, and E3 could be found. Outside this region, several open reading frames were identified without any obvious homology to known adenovirus proteins. In the region organized similarly as other adenoviral genomes, most homologies were found to an ovine adenovirus (OAV strain 287). The highest level of amino acid identity was found for the hexon proteins of EDS and OAV. The virus-associated RNA (VA RNA) was identified thanks to the homology with the VA RNA of fowl adenovirus serotype 1 (FAV1). Similarities with FAV1 were also found in the fiber protein. Our results demonstrate that the avian EDS virus represents an intermediate between mammalian and avian adenoviruses. The nucleotide sequence and genomic organization of the EDS virus reflect the heterogeneity of the aviadenovirus genus and the Adenoviridae family.

Identification of a novel sequence that governs both polyadenylation and alternative splicing in region E3 of adenovirus

Region E3 encodes four major overlapping mRNAs with different splicing patterns. There are two poly(A) sites, an upstream site called E3A and a downstream site called E3B. We have analyzed virus mutants with deletions or insertions in E3 in order to identify sequences that function in the alternative processing of E3 pre-mRNAs, and to understand what determines which poly(A) sites and which splice sites are used. In previous studies we established that the 5' boundary of the E3A poly(A) signal is at an ATTAAA sequence. We now show, using viable virus mutants, that the 3' boundary of the E3A signal is located within 47-62 nucleotides (nt) downstream of the ATTAAA (17-32 nt downstream of the last microheterogenous poly(A) addition site). Our data further suggest that the spacing between the ATTAAA, the cleavage sites, and the essential downstream sequences may be important in E3A 3' end formation. Of particular interest, these mutants suggest a novel mechanism for the control of alternative pre-mRNA processing. Mutants which are almost completely defective in E3A 3' end formation display greatly increased use of a 3' splice site located 4 nt upstream of the ATTAAA. The mRNA that uses this 3' splice site is polyadenylated at the E3B poly(A) site. We suggest, for this particular case, that alternative pre-mRNA processing could be determined by a competition between trans-acting factors that function in E3A 3' end formation or in splicing. These factors could compete for overlapping sequences in pre-mRNA.

Cloning and sequencing of a rat CuZn superoxide dismutase cDNA. Correlation between CuZn superoxide dismutase mRNA level and enzyme activity in rat and mouse tissues

The molecular cloning and nucleotide sequence of a cDNA clone (pR SOD) for rat CuZn superoxide dismutase (CuZnSOD) is reported. Nucleotide sequence homology with human superoxide dismutase is 86% for the coding region and 71% for the 3' untranslated region. The deduced amino acid sequence is given and the homologies with the sequences reported for other species are presented. Northern blot analysis of total RNA from various rat and mouse tissues and from two mouse cell lines show that pR SOD hybridizes with one mRNA species of about 0.7 kb. The amount of CuZnSOD mRNA in each tissue, measured by densitometry of the Northern blot autoradiograms, correlates with the enzymatic activity based on protein content. These results indicate that the control of CuZnSOD activity in mammalian tissues is largely dependent on the regulation of CuZnSOD mRNA levels. In human liver, fibroblasts and FG2 hepatoma cells, two CuZnSOD mRNAs (0.7 kb and 0.9 kb) are observed. The level of CuZnSOD mRNA in FG2 is 25% that of the liver and four times more abundant than in fibroblasts.

Human dihydropteridine reductase: characterisation of a cDNA clone and its use in analysis of patients with dihydropteridine reductase deficiency

Deficiency of human dihydropteridine reductase (hDHPR) causes malignant hyperphenylalaninemia. We report the isolation of a cDNA clone for hDHPR that spans the complete coding region, and present the nucleotide sequence and the predicted amino acid sequence. The hDHPR protein does not share extensive homology with the enzymatically related protein human dihydrofolate reductase. Patients with hDHPR deficiency were analysed for the presence of hDHPR cross-reacting protein, mRNA encoding hDHPR, and chromosomal DNA rearrangements. The results show that this inherited error of metabolism can result from a variety of mutations. However, no major rearrangements were seen in 11 patients analysed by Southern blotting. Three RFLPs were found with the restriction endonucleases AvaII and MspI. These RFLPs are useful for prenatal diagnosis of hDHPR deficiency.

ATTAAA as well as downstream sequences are required for RNA 3'-end formation in the E3 complex transcription unit of adenovirus

We mapped the location of the E3A RNA 3' end site in the E3 transcription unit of adenovirus 2. The procedure used was nuclease-gel analysis with 32P-labeled RNA probes. The poly(A) addition sites were microheterogeneous and were located approximately 17 to 29 nucleotides downstream from an ATTAAA sequence. To identify the sequences that make up the E3A RNA 3' end signal, we constructed five viable virus mutants with deletions in or near the E3A RNA 3' end site. The mutants were analyzed for E3A RNA 3' end formation in vivo. No effect was observed from a 47-base-pair (bp) deletion (dl716) or a 72-bp deletion (dl714) located 22 and 19 nucleotides, respectively, upstream of the ATTAAA. In contrast, E3A RNA 3' end formation was abolished by a 554-bp deletion (dl708) that removes both the ATTAAA and the poly(A) addition sites, a 124-bp deletion (dl713) that removes the ATTAAA but leaves the poly(A) addition sites, and a 65-bp deletion (dl719) that leaves the ATTAAA but removes the poly(A) addition sites. These results indicate that the ATTAAA, as well as downstream sequences, including the poly(A) addition sites, are required for E3A RNA 3' end formation.

Virus deletion mutants that affect a 3' splice site in the E3 transcription unit of adenovirus 2

Five viable virus mutants were constructed with deletions near a 3' splice site located at nucleotide 2157 in the E3 transcription unit of adenovirus 2. The mutants were examined for splicing activity at the 2157 3' splice site in vivo by nuclease-gel analysis of steady-state cytoplasmic mRNA. Splicing was not prevented by an exon deletion (dl719) that leaves 16 5'-proximal exon nucleotides intact or by intron deletions that leave 34 (dl717, dl712) or 18 (dl716) 3'-proximal intron nucleotides intact. The sequences deleted in one of these intron mutants (dl716) include the putative branchpoint site used in lariat formation during splicing. Thus, a surrogate branchpoint site apparently can be used for splicing. Another intron mutant (dl714) has a deletion that leaves 15 3'-proximal intron nucleotides intact; remarkably, this deletion virtually abolished splicing, even though the deletion is only 3 nucleotides closer to the splice site than is the deletion in dl716 which splices normally. The three nucleotides deleted in dl714 that are retained by dl716 are the sequence TGT. The TGT sequence is located on the 5' boundary of the pyrimidine-rich region upstream of the nucleotide 2157 3' splice site. Such pyrimidine-rich regions are ubiquitous at 3' splice sites. Most likely, the TGT is required for splicing at the nucleotide 2157 3' splice site. The TGT may be important because of its specific sequence or because it forms the 5' boundary of the pyrimidine-rich region.

A novel RNA from early region 3 of adenovirus-2

A novel RNA species was detected by Northern blotting among the polyadenylated nuclear transcripts from early region 3 of adenovirus-2. Preliminary mapping showed that it encompasses the E3 leader 1 and part of IVS 1. Primer extension experiments revealed that its 5' end (C) was the same as that of all E3 transcripts, and S1 nuclease mapping showed that its 3' end was a polyadenylation site (P1) known to be used in the late phase of infection. The body of this RNA is 618-619 nucleotides long and we propose to name it E3-CP1. Kinetic studies suggest that it is a primary transcript as are the E3 premessenger RNAs.

Immunological identification of rat tissue kallikrein cDNA and characterization of the kallikrein gene family

A tissue kallikrein cDNA was identified by direct immunological screening with affinity-purified anti-rat tissue kallikrein antibody from a rat submandibular cDNA library constructed with the expression vector pUC8. Sequence analysis of the kallikrein cDNA revealed an encoded protein 97% homologous to the partial amino acid sequence of rat submandibular kallikrein. This cDNA was used to hybrid-select kallikrein-specific RNA from submandibular gland. Translation of the hybrid-selected RNA in a cell-free assay system resulted in the production of a 37 kDa peptide representing the preproenzyme. In addition, hybrid-selection of RNA under less stringent conditions showed cross-hybridization with other submandibular gland mRNA species. In correlation with these results, analysis of rat genomic DNA showed extensive hybridization, suggesting a family of closely related kallikrein-like genes. Consequently, a Charon 4A rat genomic library was screened for kallikrein genes by hybridization with rat tissue kallikrein cDNA. Thirty-four clones were isolated and found to be highly homologous by hybridization and restriction enzymes analyses. Fourteen unique clones were identified by restriction enzyme site polymorphisms within DNA segments which hybridized to the kallikrein cDNA probe and it was estimated that at least 17 different kallikrein-like genes are present in the rat. Sequence and structural analysis of one of the genomic clones revealed a gene structure similar to that of other serine proteinases. Comparison of the partially sequenced exon regions of the gene with the sequence of rat tissue kallikrein cDNA reveals 89% identity when aligned for the greatest homology. However, the genomic sequence predicts termination codons in all three translational reading frames, implying that this gene is nonfunctional, i.e., a pseudogene. Comparison of the rat genomic sequence to a kallikrein-like gene from the mouse reveals extensive preservation of exons, less identity within introns and no significant homology between extragenic regions.

Region E3 of human adenoviruses; differences between the oncogenic adenovirus-3 and the non-oncogenic adenovirus-2

The nucleotide sequence of a 4379-bp-long DNA segment, located between map coordinates 76.5 and 89.2 in the Ad3 genome, was established. The segment includes the entire early transcription unit 3 (E3) and the 3'-part of the gene for the late polypeptide pVIII. The established sequence was compared to the sequence of the corresponding region in the Ad2 genome [Hérissé et al., Nucl. Acids Res. 8, (1980) 2173-2192; Hérissé and Galibert, Nucl. Acids Res. 9, (1981) 1229-1249]. Although Ad2 and Ad3 belong to different serological and oncogenic subgroups, their E3 regions are well conserved (55-60% homology). In total, the E3 region of Ad3 appears to encode eight to nine different polypeptides many of which are likely to be membrane-associated. The most conspicuous difference between the E3 regions of Ad2 and Ad3 is the presence of a 950-bp-long A + T-rich insert in the Ad3 sequence. This insert contains two open reading frames, each encoding a polypeptide with a predicted Mr of about 20,000. The mRNAs encoding these novel polypeptides were identified by S1 nuclease analysis.

Selection of sequence elements that substitute for the standard AATAAA motif which signals 3' processing and polyadenylation of late simian virus 40 mRNAs

A method is described which allows selection of sequences which can substitute for the normal AATAAA hexanucleotide involved in polyadenylation of SV40 late mRNAs. Plaques were generated from viral DNA lacking the motif, forcing acquisition of substitute sequences. Four variants were characterized. All displayed wild-type growth kinetics and produced normal levels of late mRNAs and proteins. Two variants had reacquired AATAAA elements and one acquired an ATTAAA sequence. The last variant carried an ATTTTTTAAA segment, suggesting this novel sequence, or some portion of it, can also signal poly A addition.

ATTAAA as well as downstream sequences are required for RNA 3'-end formation in the E3 complex transcription unit of adenovirus

We mapped the location of the E3A RNA 3' end site in the E3 transcription unit of adenovirus 2. The procedure used was nuclease-gel analysis with 32P-labeled RNA probes. The poly(A) addition sites were microheterogeneous and were located approximately 17 to 29 nucleotides downstream from an ATTAAA sequence. To identify the sequences that make up the E3A RNA 3' end signal, we constructed five viable virus mutants with deletions in or near the E3A RNA 3' end site. The mutants were analyzed for E3A RNA 3' end formation in vivo. No effect was observed from a 47-base-pair (bp) deletion (dl716) or a 72-bp deletion (dl714) located 22 and 19 nucleotides, respectively, upstream of the ATTAAA. In contrast, E3A RNA 3' end formation was abolished by a 554-bp deletion (dl708) that removes both the ATTAAA and the poly(A) addition sites, a 124-bp deletion (dl713) that removes the ATTAAA but leaves the poly(A) addition sites, and a 65-bp deletion (dl719) that leaves the ATTAAA but removes the poly(A) addition sites. These results indicate that the ATTAAA, as well as downstream sequences, including the poly(A) addition sites, are required for E3A RNA 3' end formation.

Virus deletion mutants that affect a 3' splice site in the E3 transcription unit of adenovirus 2

Five viable virus mutants were constructed with deletions near a 3' splice site located at nucleotide 2157 in the E3 transcription unit of adenovirus 2. The mutants were examined for splicing activity at the 2157 3' splice site in vivo by nuclease-gel analysis of steady-state cytoplasmic mRNA. Splicing was not prevented by an exon deletion (dl719) that leaves 16 5'-proximal exon nucleotides intact or by intron deletions that leave 34 (dl717, dl712) or 18 (dl716) 3'-proximal intron nucleotides intact. The sequences deleted in one of these intron mutants (dl716) include the putative branchpoint site used in lariat formation during splicing. Thus, a surrogate branchpoint site apparently can be used for splicing. Another intron mutant (dl714) has a deletion that leaves 15 3'-proximal intron nucleotides intact; remarkably, this deletion virtually abolished splicing, even though the deletion is only 3 nucleotides closer to the splice site than is the deletion in dl716 which splices normally. The three nucleotides deleted in dl714 that are retained by dl716 are the sequence TGT. The TGT sequence is located on the 5' boundary of the pyrimidine-rich region upstream of the nucleotide 2157 3' splice site. Such pyrimidine-rich regions are ubiquitous at 3' splice sites. Most likely, the TGT is required for splicing at the nucleotide 2157 3' splice site. The TGT may be important because of its specific sequence or because it forms the 5' boundary of the pyrimidine-rich region.

Novel deletion mutants that enhance a distant upstream 5' splice in the E3 transcription unit of adenovirus 2

Region E3 of adenovirus is a "complex" transcription unit: i.e. different mRNAs and proteins arise by differential RNA 3' end selection and differential splicing of the primary transcript. We are using viable virus mutants to understand the controls that dictate the specificity and efficiency of the RNA processing signals. We describe a novel class of deletion mutations that enhance a natural 5' splice site located approximately 740 nucleotides (nt) upstream. In particular, deletions within nt 1691-2044 in the E3 transcription unit result in a 5-fold enhancement of the 5' splice site at nt 951 (as reflected in steady-state mRNA). The effect is specific, because the deletions do not affect the 5' splice site at nt 372, and because deletions within nt 2044-2214 do not affect either the 951 or the 372 5' splice sites. As a consequence of the enhanced splicing at the 951 5' site, synthesis of the major E3 mRNA and the major E3 protein (gp19K) are dramatically reduced. At least one of the natural 3' splice sites, located at nt 2157, is the recipient of the enhanced splicing at the 951 5' splice site. We conclude that sequences located within nt 1691-2044 affect (probably in cis) splicing at the 951 5' splice site. We speculate that nt 1691-2044 includes a splicing control region which functions to suppress splicing at the 951 5' splice site.

Mapping the 5' ends, 3' ends, and splice sites of mRNAs from the early E3 transcription unit of adenovirus 5

Using nuclease gel analyses, the sites in the approximately 4000 nucleotide (nt) E3 transcription unit of adenovirus 5 (Ad5) that encode the 5' ends, 3' ends, and 5' and 3' splice sites of the approximately 10 E3 mRNAs were determined. Transcription initiation of all mRNAs occurs at two major (nt 1 and 8) and approximately two minor sites, situated 20-30 nt 3' to a TATA box. There are two major 3' end sites (nt 2227 and 3308), located approximately 20 nt downstream from ATTAAA and an AATAAA sequences, respectively. Thus, ATTAAA, as well as the usual AATAAA, apparently can function as a 3' end signal. There are two 5' splice sites (nt 372 and 923), both with GT at the intron boundary. There are four 3' splice sites (nt 766, 1817, 2201, and 2880), all with AG at the intron boundary. The nt 1817, 2201, and 2880 3' splice sites are located immediately upstream from open reading frames, such that splicing at the different sites allows synthesis of completely different proteins.

DNA sequence of the early E3 transcription unit of adenovirus 5

The DNA sequence of the early E3 transcription unit of adenovirus 5 (Ad5) has been determined and it has been compared to Ad2, as published previously [J. Hérissé, G. Courtois, and F. Galibert (1980), Nucl. Acids Res. 8, 2173-2192; J. Hérissé and F. Galibert (1981), Nucl. Acids Res. 9, 1229-1240]. The E3 regions of Ad5 and Ad2 are quite homologous despite being nonessential for Ad growth in cultured cells. The major differences are "gaps" that exist either in Ad5 or Ad2 in intergenic regions. The conservation of sequences suggests that E3 plays a beneficial role in natural infection of humans. E3 appears to encode about seven to nine proteins; based on sequence, seven of these may be membrane proteins. Thus, E3 may be a transcription unit devoted to the synthesis of membrane proteins. The E3 genes lie essentially one after the other along the genome, and which gene is expressed from a given primary transcript is determined by the choice of the 3' end site and the 5' and 3' splice sites. Almost all E3 mRNAs contain nonfunctional AUGs that are 5' to the initiation codon. Codon usage is nonrandom. Although the CG dinucleotide frequency is low, CG clusters exist in the promoter and other regions.

Mapping a new gene that encodes an 11,600-molecular-weight protein in the E3 transcription unit of adenovirus 2

The DNA sequence of the early E3 transcription unit of adenovirus 2 (Ad2) (J. Hérissé et al., Nucleic Acids Res. 8:2173-2192, 1980), indicates that an open reading frame exists between nucleotides 1860 and 2163 that could encode a protein of Mr 11,600 (11.6K). We have determined the DNA sequence of the corresponding region in Ad5 (closely related to Ad2) and have established that this putative gene is conserved in Ad5 (a 10.5K protein). To determine whether this protein is expressed, we prepared an antiserum in rabbits against a synthetic peptide corresponding to amino acids 66 to 74 in the 11.6K protein of Ad2. The peptide antiserum immunoprecipitated a ca. 13K-14K protein doublet, as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, from [35S]methionine-labeled Ad2- or Ad5-early-infected KB cells. The antiserum also immunoprecipitated a 13K-14K protein doublet translated in vitro from Ad2 or Ad5 early E3-specific mRNA purified by hybridization to Ad2 EcoRI-D (nucleotides -236 to 2437). The synthetic peptide successfully competed with the 13K-14K protein doublet in immunoprecipitation experiments, thereby confirming the specificity of the antiserum. As deduced from the DNA sequence, the 11.6K protein (and the corresponding 10.5K Ad5 protein) has a conserved 22-amino-acid hydrophobic domain, suggesting that the protein may be associated with membranes. We conclude that a gene located at nucleotides 1860 to 2143 in the Ad2 E3 transcription unit (nucleotides 1924 to 2203) in the Ad5 E3 transcription unit) encodes an 11.6K protein (10.5K in Ad5).

mRNAs from human adenovirus 2 early region 4

The molecular structure of the mRNAs from early region 4 of human adenovirus 2 has been studied by Northern blot analysis, S1 nuclease analysis, and sequence analysis of cDNA clones. The results make it possible to identify four different splice donor sites and six different splice acceptor sites. The structure of 12 different mRNAs can be deduced from the analysis. The mRNAs have identical 5' and 3' ends and are thus likely to be processed from a common mRNA precursor by differential splicing. The different mRNA species are formed by the removal of one to three introns, and they all carry a short 5' leader segment. The introns appear to serve two functions; they either place a 5' leader segment in juxtaposition with an open reading frame or fuse two open translational reading frames. The early region 4 mRNAs can encode at least seven unique polypeptides.

Efficient coupled transcription and mRNA splicing in vitro using plasmids derived from early region 3 of adenovirus 2 and a nondefective adenovirus-simian virus 40 hybrid

Accurate and highly efficient (80%) splicing of a single mRNA precursor to processed products was achieved using HeLa cell extracts to synthesize and process RNA in vitro from recombinant plasmids containing specific DNA segments from adenovirus 2 (Ad2) and the nondefective adenovirus-simian virus 40 (Ad+2ND1) hybrid. One plasmid, pRID, contains a segment of Ad2 DNA spanning chromosome map coordinates 75.9-83.4. The other plasmid, pRW9, contains the analogous viral region from Ad+2ND1. RNA synthesis from pRID in vitro occurs for more than 60 min and is directed by RNA polymerase II. RNA products consistent in size with the expected precursor and the two processed mRNAs are made. RNA blot hybridization analyses showed that these products are complementary to the Ad2 insert in the plasmid and that the appropriate intervening sequence was absent from the smallest processed mRNA. Comparison of the splice patterns of RNA made in vitro to those of RNAs taken from infected cells using the nuclease S1 technique demonstrated the accuracy of intron removal.

The nucleotide sequence at the recombination/integration sites of the hybrid viruses Ad2+ND3 and Ad2+ND5

The nucleotide sequence at the recombination/integration sites of the adenovirus 2-simian virus 40 hybrid viruses, Ad2+ND3 and Ad2+ND5, is reported. These viruses were obtained by passages through human cells and fail to express the SV40-related proteins. The lack of expression of SV40-related proteins has been explained on the basis of the nucleotide sequence at the recombination sites. Ad2+ND3 has the entire reading frame for the SV40 T antigen removed up to the translation termination codon. The recombination event in Ad2+ND5 was found to occur in the leader region 11 nucleotides upstream from the splice junction, thus totally eliminating the naturally occurring splice site, which might have lead to defective processing of the mRNA. Alternatively, because of the large deletion, this virus is incapable of making similar hybrid proteins as in Ad2+ND1, Ad2+ND2, and Ad2+ND4, which share the N-terminal sequence of the 16-kDa glycoprotein of the wild-type virus. Thus, either one or both of these events may explain the lack of synthesis of the SV40 T antigen specific protein. Ad2+ND3 and Ad2+ND5 share the sequences at the right junction which suggests their origin from a common precursor. Also, the recombination was found to result in the disruption of the poly (A) addition signal of the adenovirus 2 early region III transcripts. All of the junction sequences were found to be rich in A:T base pairs.

Polyadenylic acid addition sites in the adenovirus type 2 major late transcription unit

The cytoplasmic mRNAs which are transcribed from the major late adenovirus promoter can be arranged into five 3'-coterminal families, L1 to L5. We have defined the polyadenylation sites of the mRNAs that belong to the five families at the nucleotide level. From the results, the following conclusions can be made. (i) The hexanucleotide sequence AAUAAA is present at the 3' end of all late adenovirus type 2 mRNAs and precedes the site of polyadenylation by 12 to 30 nucleotides. (ii) Between one and three A residues are present in the genomic sequence at the polyadenylation site. (iii) A sequence with the composition (T)n (A)p (T)q (n, p, q greater than or equal to 1) is found 4 to 24 nucleotides beyond all the adenovirus-specific polyadenylation sites except the 3'-coterminal family L4. This sequence is also found beyond many cellular polyadenylation sites. (iv) The L1 and L2 polyadenylation sites are very similar in structure. The other polyadenylation sites show no apparent sequence relationship, except for the hexanucleotide sequence.

Structure of three spliced mRNAs from region E3 of adenovirus type 2

A cDNA library representing early adenovirus type 2 (Ad2) mRNA was constructed. The cDNA copies were inserted into the PstI cleavage site of the pBR322 plasmid, and clones containing sequences from region E3 of the Ad2 genome were identified by colony hybridization. Selected clones were characterized by restriction enzyme cleavage, hybridization, and partial DNA sequence analysis. The precise structure of three spliced mRNAs was established by comparing the results with the DNA sequence of region E3 from Ad2 (Herissé et al., Nucl. Acids Res. 8 (1980) 2173--2191; Herissé and Galibert, Nucl. Acids Res. 9 (1981) 1229--1249). One of the characterized mRNA species encodes the E3/19K glycoprotein, whereas the other two most likely encode the E3/14K protein. The results demonstrate, moreover, that certain splice points which are used to generate the major E3 mRNAs are also used to splice the supplementary leader segments to the fibre mRNA at late times after infection. Two separate poly(A)-addition sites were identified in region E3 by analysis of the cDNA clones; one is preceded by the hexanucleotide sequence AAUAAA, whereas the other is preceded by an altered hexanucleotide, having the sequence AUUAAA.