Complete Characterization of the Human ABC Gene Family

The human ATP-binding cassette (ABC) transporters comprise a large family of membrane transport proteins and play a vital role in many cellular processes. The genes provide functions as diverse as peptide transport, cholesterol and sterol transport, bile acid, retinoid, and iron transport. In addition some ABC genes play a role as regulatory elements. Many ABC genes play a role in human genetic diseases, and several are critical drug transport proteins overexpressed in drug resistant cells. Analysis of the gene products allows the genes to be grouped into seven different subfamilies.     

Determination of the Processing Sites of an Arabidopsis 2S Albumin and Characterization of the Complete Gene Family

The most abundant isoform of the 2S albumin present in seeds of Arabidopsis thaliana has been sequenced and the corresponding gene isolated. Examination of the protein and DNA sequences allows the determination of the exact proteolytic cleavage sites during posttranslational processing. Like other 2S albumins, that of Arabidopsis is made as a prepropeptide. After removal of the signal peptide, the propeptide is cleaved at four other points, giving two subunits linked by a disulfide bridge(s). Comparison of these cleavage sites with those of 2S albumins of Brassica napus and Bertholletia excelsa suggests that while individual cleavage sites between species are conserved, the four processing sites within a species are not similar, suggesting that up to four different proteases may be involved in processing 2S albumins. The Arabidopsis 2S albumin gene was used to isolate the entire gene family. There are four genes, tightly linked in a tandem array. None of the genes contains an intron. Comparison of the predicted protein sequences shows that only one of the genes can encode the isoform determined by protein analysis to be the most abundant, and therefore this gene is certain to be expressed. It is possible that some or all of the other three genes are also active.     

Structure of Brassica napus Phosphoenolpyruvate Carboxylase Genes: Missing Introns Causing Polymorphisms among Gene Family Members

The Brassica napus genome contains more than four phospho enol pyruvate carboxylase (PEPCase) genes. Although the nucleotide sequences of these genes highly resemble each otehr, an intron corresponding to the 7th intron in the maize gene is present in PE15- and PE105-PEPCase genes but absent in PE3-PEPCase. The intron corresponding to the maize 3rd intron is absent in PE15- and PE105-PEPCase genes. Deletion of these introns occurred precisely such that the coding sequence is faithfully preserved with respect to the maize gene. The PE19-PEPCase gene contains a deletion in the 8th exon instead of the presence of those introns.     

Molecular Determinants for Functional Differences between Alanine-Serine-Cysteine Transporter 1 and Other Glutamate Transporter Family Members

The ASCTs (alanine, serine, and cysteine transporters) belong to the solute carrier family 1 (SLC1), which also includes the human glutamate transporters (excitatory amino acid transporters, EAATs) and the prokaryotic aspartate transporter Glt_Ph. Despite the high degree of amino acid sequence identity between family members, ASCTs function quite differently from the EAATs and Glt_Ph. The aim of this study was to mutate ASCT1 to generate a transporter with functional properties of the EAATs and Glt_Ph, to further our understanding of the structural basis for the different transport mechanisms of the SLC1 family. We have identified three key residues involved in determining differences between ASCT1, the EAATs and Glt_Ph. ASCT1 transporters containing the mutations A382T, T459R, and Q386E were expressed in Xenopus laevis oocytes, and their transport and anion channel functions were investigated. A382T and T459R altered the substrate selectivity of ASCT1 to allow the transport of acidic amino acids, particularly l-aspartate. The combination of A382T and T459R within ASCT1 generates a transporter with a similar profile to that of Glt_Ph, with preference for l-aspartate over l-glutamate. Interestingly, the amplitude of the anion conductance activated by the acidic amino acids does not correlate with rates of transport, highlighting the distinction between these two processes. Q386E impaired the ability of ASCT1 to bind acidic amino acids at pH 5.5; however, this was reversed by the additional mutation A382T. We propose that these residues differences in TM7 and TM8 combine to determine differences in substrate selectivity between members of the SLC1 family.     

Two Novel Human Members of an Emerging Mammalian Gene Family Related to Mono-ADP-Ribosylating Bacterial Toxins

Mono-ADP-ribosylation is one of the posttranslational protein modifications regulating cellular metabolism, e.g., nitrogen fixation, in prokaryotes. Several bacterial toxins mono-ADP-ribosylate and inactivate specific proteins in their animal hosts. Recently, two mammalian GPI-anchored cell surface enzymes with similar activities were cloned (designated ART1 and ART2). We have now identified six related expressed sequence tags (ESTs) in the public database and cloned the two novel human genes from which these are derived (designatedART3andART4). The deduced amino acid sequences of the predicted gene products show 28% sequence identity to one another and 32–41% identity vs the muscle and T cell enzymes. They contain signal peptide sequences characteristic of GPI anchorage. Southern Zoo blot analyses suggest the presence of related genes in other mammalian species. By PCR screening of somatic cell hybrids and byin situhybridization, we have mapped the two genes to human chromosomes 4p14–p15.1 and 12q13.2–q13.3. Northern blot analyses show that these genes are specifically expressed in testis and spleen, respectively. Comparison of genomic and cDNA sequences reveals a conserved exon/intron structure, with an unusually large exon encoding the predicted mature membrane proteins. Secondary structure prediction analyses indicate conserved motifs and amino acid residues consistent with a common ancestry of this emerging mammalian enzyme family and bacterial mono(ADP-ribosyl)transferases. It is possible that the four human gene family members identified so far represent the “tip of an iceberg,” i.e., a larger family of enzymes that influences the function of target proteins via mono-ADP-ribosylation.     

人血清白蛋白基因的打靶研究

为获得整合有人血清白蛋白(HSA)基因的猪胎儿成纤维细胞克隆,从猪基因组文库中杂交筛选得到猪血清白蛋白(PSA)基因全序列35kb并克隆了人血清白蛋白cDNA序列,扩增猪血清白蛋白基因5′调控序列7.2kb片段及第一内含子至第四内含子2.8kb的片段;构建了含有neo及tk正负筛选标记基因的人血清白蛋白基因打靶载体,并验证了neo基因的有效性。将线性化的打靶载体通过电击转染的方法整合到猪胎儿成纤维细胞基因组中,利用G418及GANC进行细胞克隆的抗药性筛选,PCR及Southern blot鉴定抗药性细胞克隆,最终获得3个发生同源重组的细胞克隆。这为下一步进行体细胞核移植制备生产人血清白蛋白转基因猪奠定了基础。     

Functional Relationship between Protein Disulfide Isomerase Family Members during the Oxidative Folding of Human Secretory Proteins

To examine the relationship between protein disulfide isomerase family members within the mammalian endoplasmic reticulum, PDI, ERp57, ERp72, and P5 were depleted with high efficiency in human hepatoma cells, either singly or in combination. The impact was assessed on the oxidative folding of several well-characterized secretory proteins. We show that PDI plays a predominant role in oxidative folding because its depletion delayed disulfide formation in all secretory proteins tested. However, the phenotype was surprisingly modest suggesting that other family members are able to compensate for PDI depletion, albeit with reduced efficacy. ERp57 also exhibited broad specificity, overlapping with that of PDI, but with preference for glycosylated substrates. Depletion of both PDI and ERp57 revealed that some substrates require both enzymes for optimal folding and, furthermore, led to generalized protein misfolding, impaired export from the ER, and degradation. In contrast, depletion of ERp72 or P5, either alone or in combination with PDI or ERp57 had minimal impact, revealing a narrow substrate specificity for ERp72 and no detectable role for P5 in oxidative protein folding.     

Complete Genomic Sequence of the Human Retinoblastoma Susceptibility Gene

A 180,388-bp contig encompassing the human retinoblastoma gene was sequenced in its entirety. Partial analysis of the sequence revealed (1) a high (A + T)/(G + C) ratio and a high density of Line-1 (L1) repeat sequences, suggesting that the locus maps to G-bands 13q14.12 or 13q14.2; (2) Alu repeats that are asymmetrically oriented over a region extending 87 kb; (3) an overabundance of non-Alu-associated poly(A) tracts 10 bp or larger oriented in the antisense rather than the sense direction (36 vs 6); (4) an Alu sequence nested within an L1 repeat, indicating that the expansion of L1 repeats predates at least some of the Alu expansions; (5) at least three newly discovered microsatellite polymorphisms, one of which was subsequently found to be identical to a polymorphism in a microsatellite-based linkage map of the human genome published by another group; and (6) the basis of previously discovered intragenic RFLPs. This sequence should enhance studies of this locus and of the organization of the human genome.     

Replicative Bypass of Abasic Site in Escherichia coli and Human Cells: Similarities and Differences

Abasic [apurinic/apyrimidinic (AP)] sites are the most common DNA damages, opposite which dAMP is frequently inserted (‘A-rule’) in Escherichia coli. Nucleotide insertion opposite the AP-site in eukaryotic cells depends on the assay system and the type of cells. Accordingly, a ‘C-rule’, ‘A-rule’, or the lack of specificity has been reported. DNA sequence context also modulates nucleotide insertion opposite AP-site. Herein, we have compared replication of tetrahydrofuran (Z), a stable analog of AP-site, in E. coli and human embryonic kidney 293T cells in two different sequences. The efficiency of translesion synthesis or viability of the AP-site construct in E. coli was less than 1%, but it was 7- to 8-fold higher in the GZGTC sequence than in the GTGZC sequence. The difference in viability increased even more in pol V-deficient strains. Targeted one-base deletions occurred in 63% frequency in the GZG and 68% frequency in GZC sequence, which dropped to 49% and 21%, respectively, upon induction of SOS. The full-length products with SOS primarily involved dAMP insertion opposite the AP-site, which occurred in 49% and 71% frequency, respectively, in the GZG and GZC sequence. dAMP insertion, largely carried out by pol V, was more efficient when the AP-site was a stronger replication block. In contrast to these results in E. coli, viability was 2 to 3 orders of magnitude higher in human cells, and the ‘A-rule’ was more rigidly followed. The AP-site in the GZG and GZC sequences gave 76% and 89%, respectively, Z→T substitutions. In human cells, targeted one-base deletion was undetectable, and dTMP>dCMP were the next preferred nucleotides inserted opposite Z. siRNA knockdown of Rev1 or pol ζ established that both these polymerases are vital for AP-site bypass, as demonstrated by 36–67% reduction in bypass efficiency. However, neither polymerase was indispensable, suggesting roles of additional DNA polymerases in AP-site bypass in human cells.     

Inclusive Fitness and Human Family Structure

The implications of sociobiology, and especially of "inclusive fitness" or "kin-selection" theory, to human family structures are explored. Kin-selection theory provides a model to formulate testable hypotheses predicting cooperation and conflict for categories of kinsmen; it also suggests an alternative way of looking at incest, endogamy, exogamy, rule of descent, and type of marriage in terms of such biological concepts as mating strategies, inclusive fitness, parental investment, and sexual dimorphism and bimaturism. [sociobiology, kin-selection theory, inclusive fitness, family structure, marriage]     

Tissue and Cellular Expression Patterns of Porcine CFTR: Similarities to and Differences From Human CFTR

Emerging porcine models of cystic fibrosis (CF) are expected to mimic the human disease more closely than current mouse models do. However, little is known of the tissue and cellular expression patterns of the porcine CF transmembrane conductance regulator (pCFTR) and possible differences from human CFTR (hCFTR). Here, the expression pattern of pCFTR was systematically established on the mRNA and protein levels. Using specific anti-pCFTR antibodies, the majority of the protein was immunohistochemically detected on paraffin-embedded sections and on cryostate sections in the apical cytosol of intestinal crypt epithelial cells, nasal, tracheal, and bronchial epithelial cells, and other select, mostly glandular epithelial cells. Confocal laser scanning microscopy with co-localization of the Golgi marker 58K localized the protein in the cytosol between the Golgi apparatus and the apical cell membrane with occasional punctate or diffuse staining of the apical membrane. The tissue and cellular distribution patterns were confirmed by RT-PCR from whole tissue lysates or select cells after laser capture microdissection. Thus, expression of pCFTR was found to largely resemble that of hCFTR except for the kidney, brain, and cutaneous glands, which lack expression in pigs. Species-specific differences between pCFTR and hCFTR may become relevant for future interpretations of the CF phenotype in pig models. (J Histochem Cytochem 58:785–797, 2010)