BiP/Kar2p serves as a molecular chaperone during carboxypeptidase Y folding in yeast.

Although transiently associated with numerous newly synthesized proteins, BiP has not been shown to be an essential component directly linked to the folding and oligomerization of newly synthesized proteins in the endoplasmic reticulum. To determine whether it is needed as a molecular chaperone, we analyzed the maturation of an endogenous yeast glycoprotein, carboxypeptidase Y (CPY) in several yeast strains with temperature-sensitive mutations in BiP. These kar2 mutant strains have previously been found to be defective in translocation at the nonpermissive temperature (Vogel, J. P., L. M. Misra, and M. D. Rose, 1990. J. Cell Biol, 110:1885-1895). To circumvent the translocation block, we used DTT at permissive temperature to delay folding and intracellular transport. We then followed the maturation of the ER-retained CPY after shifting to the nonpermissive temperature and dilution of the DTT. Without the functional chaperone, CPY aggregated, failed to be oxidized, and remained in the ER. In contrast to wild-type cells, in which BiP binding was transient with no more than 10-15% of labeled CPY associated at any time, 30-100% of the CPY remained associated with BiP in the mutant strains. In a heterozygous diploid strain, CPY matured and exited the ER normally. Taken together, the results provide clear evidence that BiP plays a critical role as a molecular chaperone in CPY folding.

Gene expression analysis by transcript profiling coupled to a gene database query.

We describe an mRNA profiling technique for determining differential gene expression that utilizes, but does not require, prior knowledge of gene sequences. This method permits high-throughput reproducible detection of most expressed sequences with a sensitivity of greater than 1 part in 100,000. Gene identification by database query of a restriction endonuclease fingerprint, confirmed by competitive PCR using gene-specific oligonucleotides, facilitates gene discovery by minimizing isolation procedures. This process, called GeneCalling, was validated by analysis of the gene expression profiles of normal and hypertrophic rat hearts following in vivo pressure overload.

Open systems: panoramic views of gene expression.

Since their development in the early 1990s, differential gene expression (DGE) technologies have been applied to a multitude of biological challenges, both for the purpose of basic biological research and as a valuable tool for the discovery and development of pharmaceuticals. In this review we survey a class of DGE technologies collectively referred to as 'open' architecture systems. These technologies are distinct from the 'closed' DGE technologies (quantitative PCR, chip technologies), in that no pre-existing biological or sequence information is necessary and they are applicable to any species. Examples of open systems include GeneCalling, SAGE, TOGA, READS, and their progenitor DGE technologies, differential display and cDNA representational difference analysis. We review these technologies and summarize a specific application using GeneCalling for novel gene discovery. Additionally, the significance of data management and experimental design in this new age of expression analysis is discussed.

Patterns of nucleotide misincorporations during enzymatic amplification and direct large-scale sequencing of ancient DNA.

Whereas evolutionary inferences derived from present-day DNA sequences are by necessity indirect, ancient DNA sequences provide a direct view of past genetic variants. However, base lesions that accumulate in DNA over time may cause nucleotide misincorporations when ancient DNA sequences are replicated. By repeated amplifications of mitochondrial DNA sequences from a large number of ancient wolf remains, we show that C/G-to-T/A transitions are the predominant type of such misincorporations. Using a massively parallel sequencing method that allows large numbers of single DNA strands to be sequenced, we show that modifications of C, as well as to a lesser extent of G, residues cause such misincorporations. Experiments where oligonucleotides containing modified bases are used as templates in amplification reactions suggest that both of these types of misincorporations can be caused by deamination of the template bases. New DNA sequencing methods in conjunction with knowledge of misincorporation processes have now, in principle, opened the way for the determination of complete genomes from organisms that became extinct during and after the last glaciation.

Host-derived 5' ends and overlapping complementary 3' ends of the two mRNAs transcribed from the ambisense S segment of Uukuniemi virus.

Two mRNAs, coding for the N and NSS proteins, are transcribed from the small (S) Uukuniemi virus RNA segment by an ambisense strategy (J. F. Simons, U. Hellman, and R. F. Pettersson, J. Virol. 64:247-255, 1990). In this report, we describe the analysis of the 5' and 3' ends of the two mRNAs. Primer extension as well as cloning and sequencing of individual mRNAs showed that the 5' ends of both mRNAs contained nonviral sequences ranging from 7 to 25 residues in length (mean, 12 residues), indicating a cap-snatching mechanism similar to the one originally described for priming of influenza virus mRNA synthesis. In 35% of the cases, the first virion-specified nucleotide (an A residue) was substituted with a G residue. Between the translation termination codons of N and NSS, there is a 74-residue-long noncoding intergenic region (Simons et al., J. Virol. 64:247-255, 1990). Nuclease protection assays using both RNA and DNA hybridization probes showed that the 3' ends of the N and NSS mRNAs overlap each other by about 100 nucleotides. The 3' end of the NSS mRNA extends into the coding sequence of the N mRNA, whereas the N mRNA is terminated just prior to the stop codon of NSS. To our knowledge, this is the first example of overlapping complementary mRNAs in viruses with an ambisense coding strategy. No obvious transcription termination sequence was identified. However, because of a short palindromic sequence in the intergenic region, the 3' ends of both mRNAs (and consequently also the template RNAs) can be folded into an A/U-rich hairpin structure. It remains to be determined whether this structure plays any role in transcription termination.

Production of Labeled cRNA Probes without Vector Cloning: Application to Localization of Basic Fibroblast Growth Factor and Tyrosine Hydroxylase mRNAs by in Situ Hybridization Histochemistry.

We describe an approach for generating labeled, single-stranded cRNA probes, using the polymerase chain reaction with primers containing RNA polymerase promoter sequences. Transcription reactions using the amplified products and RNA polymerases yield, for the most part, full-length products. cRNA probes for basic fibroblast growth factor and tyrosine hydroxylase which have incorporated (35) S-labeled nucleotides were used successfully for in situ hybridization histochemistry. This method provides a significantly faster, less work-intensive procedure for obtaining labeled single-stranded RNA useful for nucleic acid hybridization studies.

Endoplasmic reticulum glucosidase II is composed of a catalytic subunit, conserved from yeast to mammals, and a tightly bound noncatalytic HDEL-containing subunit.

Trimming of glucoses from N-linked core glycans on newly synthesized glycoproteins occurs sequentially through the action of glucosidases I and II in the endoplasmic reticulum (ER). We isolated enzymatically active glucosidase II from rat liver and found that, in contrast with previous reports, it contains two subunits (alpha and beta). Sequence analysis of peptides derived from them allowed us to identify their corresponding human cDNA sequences. The sequence of the alpha subunit predicted a soluble protein (104 kDa) devoid of known signals for residence in the ER. It showed homology with several other glucosidases but not with glucosidase I. Among the homologues, we identified a Saccharomyces cerevisiae gene, which we showed by gene disruption experiments to be the functional catalytic subunit of glucosidase II. The disrupted yeast strains had no detectable growth defect. The sequence of the beta subunit (58 kDa) showed no sequence homology with other known proteins. It encoded a soluble protein rich in glutamic and aspartic acid with a putative ER retention signal (HDEL) at the C terminus. This suggested that the beta subunit is responsible for the ER localization of the enzyme.

Cell wall 1,6-beta-glucan synthesis in Saccharomyces cerevisiae depends on ER glucosidases I and II, and the molecular chaperone BiP/Kar2p.

The role of glucose trimming in the endoplasmic reticulum of Saccharomyces cerevisiae was investigated using glucosidase inhibitors and mutant strains devoid of glucosidases I and II. These glucosidases are responsible for removing glucose residues from the N-linked core oligosaccharides attached to newly synthesized polypeptide chains. In mammalian cells they participate together with calnexin, calreticulin and UDP-glucose:glycoprotein glucosyltransferase in the folding and quality control of newly synthesized glycoproteins. In S.cerevisiae, glucosidase II is encoded by the GLS2 gene, and glucosidase I, as suggested here, by the CWH41 gene. Using castanospermine (an alpha-glucosidase inhibitor) and yeast strains defective in glucosidase I, glucosidase II and BiP/Kar2p, it was demonstrated that cell wall synthesis depends on the two glucosidases and BiP/Kar2p. In double mutants with defects in both BiP/Kar2p and either of the glucosidases the phenotype was particularly clear: synthesis of 1,6-beta-glucan_a cell wall component_was reduced; the cell wall displayed abnormal morphology; the cells aggregated; and their growth was severely inhibited. No defects in protein folding or secretion could be detected. We concluded that glucose trimming in S.cerevisiae is necessary for proper cell wall synthesis, and that the glucosidases function synergistically with BiP/Kar2p in this process.

Uukuniemi virus S RNA segment: ambisense coding strategy, packaging of complementary strands into virions, and homology to members of the genus Phlebovirus.

We determined the complete nucleotide sequence of the small (S) RNA segment of Uukuniemi virus, the prototype of the Uukuvirus genus within the Bunyaviridae family. The RNA, which is 1,720 nucleotides long, contains two nonoverlapping open reading frames. The 5' end of one strand (complementary to the viral strand) encodes the nonstructural protein NSs (273 residues; molecular weight, 32,019), whereas the 5' end of the viral-sense strand encodes the nucleocapsid protein N (254 residues; molecular weight, 28,508). Thus, the S RNA uses an ambisense coding strategy previously described for the S segment of two phleboviruses and the arenaviruses. The localization of the N protein within the S RNA sequence was confirmed by amino-terminal sequence analysis of all five possible cyanogen bromide fragments obtained from purified N protein. Northern (RNA) blot analyses with strand-specific probes showed that the N and NSs proteins are translated from subgenomic mRNAs about 800 and 850 nucleotides long, respectively. These mRNAs are apparently transcribed from full-length S RNAs of opposite polarities. The two mRNA species were also detected in virus-infected cells. Interestingly, highly purified virions contained full-length S RNA copies of both polarities at a ratio of about 10:1. In contrast, virions contained exclusively negative-strand copies of the M RNA segment. The possible significance of these results for viral infection is discussed. The amino acid sequence of the N protein showed 35 and 32% homology (identity) with the N protein of Punta Toro and sandfly fever Sicilian viruses, two members of the Phlebovirus genus. The NSs proteins were much less related (about 15% identity). In addition, the extreme 5' and 3' ends of the S RNA, which are complementary to each other, also showed a high degree of conservation with the two phleboviruses. These results indicate that the uukuviruses and phleboviruses are evolutionarily related and suggest that the two genera could be merged into a single genus within the Bunyaviridae family.

Association of the nonstructural protein NSs of Uukuniemi virus with the 40S ribosomal subunit.

The small RNA segment (S segment) of Uukuniemi (UUK) virus encodes two proteins, the nucleocapsid protein (N) and a nonstructural protein (NSs), by an ambisense strategy. The function of NSs has not been elucidated for any of the bunyaviruses expressing this protein. We have now expressed the N and NSs proteins in Sf9 insect cells by using the baculovirus expression system. High yields of both proteins were obtained. A monospecific antibody was raised against gel-purified NSs and used to study the synthesis and localization of the protein in UUK virus-infected BHK21 cells. While the N protein was detected as early as 4 h postinfection (p.i.), NSs was identified only after 8 h p.i. Both proteins were still synthesized at high levels at 24 h p.i. The half-life of NSs was about 1.5 h, while that of the N protein was several hours. Sucrose gradient fractionation of [35S]methionine-labeled detergent-solubilized extracts of infected BHK21 cells indicated that NSs was firmly associated with the 40S ribosomal subunit. This association took place shortly after translation and was partially resistant to 1 M NaCl. NSs expressed by using the T7 vaccinia virus expression system, as well as in vitro-translated NSs, was also associated with the 40S subunit. In contrast, in vitro-translated N protein was found on top of the gradient. Immunolocalization of NSs, in UUK virus-infected cells, by using an affinity-purified antibody showed a granular cytoplasmic staining. A very similar pattern was seen for cells expressing NSs from a cDNA copy by using a vaccinia virus expression system. No staining was observed in the nuclei in either case. Furthermore, NSs was found neither in virions nor in nucleocapsids isolated from infected cells. In vivo labeling with 32Pi indicated that NSs is not phosphorylated. The possible function of NSs is discussed in light of these results.

N-linked oligosaccharides are necessary and sufficient for association of glycosylated forms of bovine RNase with calnexin and calreticulin.

Calnexin and calreticulin are lectin-like molecular chaperones that promote folding and assembly of newly synthesized glycoproteins in the endoplasmic reticulum. While it is well established that they interact with substrate monoglucosylated N-linked oligosaccharides, it has been proposed that they also interact with polypeptide moieties. To test this notion, glycosylated forms of bovine pancreatic ribonuclease (RNase) were translated in the presence of microsomes and their folding and association with calnexin and calreticulin were monitored. When expressed with two N-linked glycans in the presence of micromolar concentrations of deoxynojirimycin, this small soluble protein was found to bind firmly to both calnexin and calreticulin. The oligosaccharides were necessary for association, but it made no difference whether the RNase was folded or not. This indicated that unlike other chaperones, calnexin and calreticulin do not select their substrates on the basis of folding status. Moreover, enzymatic removal of the oligosaccharide chains using peptide N-glycosidase F or removal of the glucoses by ER glucosidase II resulted in dissociation of the complexes. This indicated that the lectin-like interaction, and not a protein-protein interaction, played the central role in stabilizing RNase-calnexin/calreticulin complexes.

Nucleotide sequence and coding strategy of the Uukuniemi virus L RNA segment.

The complete nucleotide sequence of the L RNA segment of Uukuniemi virus has been determined from cloned cDNA. The L RNA is 6423 nucleotides in length, and is of negative polarity. The viral-complementary RNA contains a single large open reading frame of 2104 codons which corresponds to the L protein (M(r) 241039). Comparison with the L protein sequences of other members of the Bunyaviridae showed homology with the Rift Valley fever phlebovirus L protein (38% amino acid identity), but no detectable similarity with bunyavirus, hantavirus or tospovirus L proteins. These data lend further support for the recent reclassification of uukuviruses and phleboviruses into the same genus, Phlebovirus, in the family Bunyaviridae. The L RNA sequence completes the determination of the Uukuniemi virus genome: since the M RNA segment is 3229 and the S RNA segment 1720 nucleotides, the whole genome comprises 11372 nucleotides.