Why are there still over 1000 uncharacterized yeast genes?

The yeast genetics community has embraced genomic biology, and there is a general understanding that obtaining a full encyclopedia of functions of the approximately 6000 genes is a worthwhile goal. The yeast literature comprises over 40,000 research papers, and the number of yeast researchers exceeds the number of genes. There are mutated and tagged alleles for virtually every gene, and hundreds of high-throughput data sets and computational analyses have been described. Why, then, are there >1000 genes still listed as uncharacterized on the Saccharomyces Genome Database, 10 years after sequencing the genome of this powerful model organism? Examination of the currently uncharacterized gene set suggests that while some are small or newly discovered, the vast majority were evident from the initial genome sequence. Most are present in multiple genomics data sets, which may provide clues to function. In addition, roughly half contain recognizable protein domains, and many of these suggest specific metabolic activities. Notably, the uncharacterized gene set is highly enriched for genes whose only homologs are in other fungi. Achieving a full catalog of yeast gene functions may require a greater focus on the life of yeast outside the laboratory.     

Gene patents: socially acceptable monopolies or an unnecessary hindrance to research?

Why should patents be granted on genes? This question is a provocative and troubling issue currently facing society. Looking at the commercial realities of gene patents, I conclude that on balance their effect is to retard, rather than to stimulate, both scientific and economic progress. The monopolies awarded by patents on genes as novel chemicals are not therefore in the public interest. Society would benefit from immediate change in the policy of patent offices to limit the allowance of patents on genes to specified uses with only narrow claims.     

Interaction between heme oxygenase-1 and -2 proteins

The three isoforms of heme oxygenase (HO), the rate-limiting enzyme in heme degradation, are the products of different genes that show marked differences in regulation and expression. Why is there redundancy in the heme degradation pathway, and why are there differences in tissue expression of HO isoenzymes are unanswered questions? An interaction between HO-1 and HO-2 is suspected by the co-localization of these enzymes in the lung and regions of the brain. Using multiple models and assays, we demonstrated an interaction between HO-1 and HO-2 at amino acids 0-45 of HO-2 and amino acids 58-80 of HO-1. The latter corresponds to a highly conserved, hydrophilic, and exposed region of the protein. Furthermore, the observed activity of the HO-1.HO-2 complex was lower than that expected from the sum of HO-1- and HO-2-derived activities, suggesting that this interaction serves to limit HO enzymatic activity. We speculate that this HO-1.HO-2 protein interaction may promote non-enzymatic functions of HO.     

Genomic imprinting in mammals-epigenetic parental memories

Genomic imprinting is an epigenetic phenomenon that brings the difference of expression between paternally or maternally derived alleles and is specific for mammals in vertebrates. This imprint is established in the parental germlines and then inherited to the next generation to regulate expression of imprinted genes that are essential to support proper embryonic development. More than one hundred imprinted genes have been identified in mice and humans. Some are essential for embryonic development, especially placental formation, and others regulate metabolism, behavior and physiological functions. In humans, disruption of genomic imprinting causes several diseases, including cancer. Recently, the molecular mechanisms of genomic imprinting are getting clarified. How do parents regulate gene expression of their children? Why and how is genomic imprinting evolved in mammals? The review offers a handful of recent progress in this area.     

The chemical bases of the various AIDS epidemics: Recreational drugs,anti-viral chemotherapy and malnutrition

In 1981 a new epidemic of about two-dozen heterogeneous diseases began to strike non-randomly growing numbers of male homosexuals and mostly male intravenous drug users in the US and Europe. Assuming immunodeficiency as the common denominator the US Centers for Disease Control (CDC) termed the epidemic, AIDS, for acquired immunodeficiency syndrome. From 1981-1984 leading researchers including those from the CDC proposed that recreational drug use was the cause of AIDS, because of exact correlations and of drug-specific diseases. However, in 1984 US government researchers proposed that a virus, now termed human immunodeficiency virus (HIV), is the cause of the non-random epidemics of the US and Europe but also of a new, sexually random epidemic in Africa. The virus-AIDS hypothesis was instantly accepted, but it is burdened with numerous paradoxes, none of which could be resolved by 2003: Why is there no HIV in most AIDS patients, only antibodies against it? Why would HIV take 10 years from infection to AIDS? Why is AIDS not self-limiting via antiviral immunity? Why is there no vaccine against AIDS? Why is AIDS in the US and Europe not random like other viral epidemics? Why did AIDS not rise and then decline exponentially owing to antiviral immunity like all other viral epidemics? Why is AIDS not contagious? Why would only HIV carriers get AIDS who use either recreational or anti-HIV drugs or are subject to malnutrition? Why is the mortality of HIV-antibody-positives treated with anti-HIV drugs 7–9%, but that of all (mostly untreated) HIV-positives globally is only 1–4%? Here we propose that AIDS is a collection of chemical epidemics, caused by recreational drugs, anti-HIV drugs, and malnutrition. According to this hypothesis AIDS is not contagious, not immunogenic, not treatable by vaccines or antiviral drugs, and HIV is just a passenger virus. The hypothesis explains why AIDS epidemics strike non-randomly if caused by drugs and randomly if caused by malnutrition, why they manifest in drug- and malnutrition-specific diseases, and why they are not self-limiting via anti-viral immunity. The hypothesis predicts AIDS prevention by adequate nutrition and abstaining from drugs, and even cures by treating AIDS diseases with proven medications.     

It's easier to get along with the quiet neighbours

Why are neighbouring genes co‐expressed at the RNA level? While it is tempting to think that this is to enable coordination of functionally related proteins, analysis of human proteomics data by Rappsilber and colleagues (Kustatscher et al, 2017 ) suggests this is the exception not the rule. Rather it might either be just something that happens or, in some instances, an epiphenomenon of coordination of expression to enable reduced gene expression noise.     

Isolation and sequence analysis of a hybrid delta-globin pseudogene from the brown lemur

The β-globin gene cluster of the brown lemur, a prosimian, is very short and contains a single ?-, γ- and β-globin gene, with an additional β-related gene sequence between the γ- and β-globin genes. Brown lemur DNA was cloned into the bacteriophage vector λL47.1 and a recombinant was isolated which contained an 11 × 10³ base insert including the β-globin gene and the additional putative β-globin pseudogene. The nucleotide sequence of this β-related gene was completely determined. A complete gene sequence was found, containing four frameshift mutations sufficient to establish its pseudogene status. The gene was interrupted by two intervening sequences with sizes and locations typical of mammalian β-related globin genes. The pseudogene sequence was compared in detail with human ?-, γ-, δ- and β-globin genes. The beginning of the pseudogene, from the 5′ flanking region to the second exon, was homologous to the corresponding regions of the human ?- and γ-globin genes. In contrast, the second intron, third exon and 3′ flanking region showed a remarkably close homology to the δ-globin, but not β-globin, gene of man. This suggests that the δ-globin gene is not the product of a recent gene duplication, but instead is present in most or all primates. This gene has been silenced on at least two separate occasions in primate evolution (in lemurs and in old world monkeys). In addition, the 5′ end of the lemur ψδ gene appears to have exchanged sequences with an ?- or γ-globin gene, and an analogous exchange with the β-globin gene seems to have occurred recently in the human δ-globin gene. The evolution and function of the δ-globin gene are discussed.     

The cell biology of human hair follicle pigmentation

Although we have made significant progress in understanding the regulation of the UVR‐exposed epidermal‐melanin unit, we know relatively little about how human hair follicle pigmentation is regulated. Progress has been hampered by gaps in our knowledge of the hair growth cycle’s controls, to which hair pigmentation appears tightly coupled. However, pigment cell researchers may have overly focused on the follicular melanocytes of the nocturnal and UVR‐shy mouse as a proxy for human epidermal melanocytes. Here, I emphasize the epidermis‐follicular melanocyte pluralism of human skin, as research models for vitiligo, alopecia areata and melanoma, personal care/cosmetics innovation. Further motivation could be in finding answers to why hair follicle and epidermal pigmentary units remain broadly distinct? Why melanomas tend to originate from epidermal rather than follicular melanocytes? Why multiple follicular melanocyte sub‐populations exist? Why follicular melanocytes are more sensitive to aging influences? In this perspective, I attempt to raise the status of the human hair follicle melanocyte and highlight some species‐specific issues involved which the general reader of the pigmentation literature (with its substantial mouse‐based data) may not fully appreciate.     

Single nucleotide polymorphisms of thrifty genes for energy metabolism: evolutionary origins and prospects for intervention to prevent obesity-related diseases

The "thrifty" genotype and phenotype that save energy are detrimental to the health of people living in affluent societies. Individual differences in energy metabolism are caused primarily by single nucleotide polymorphisms (SNPs), some of which promote the development of obesity/type 2 diabetes mellitus. In this review, four major questions are addressed: (1) Why did regional differences in energy metabolism develop during evolution? (2) How do genes respond to starvation and affluence? (3) Which SNPs correspond to the hypothetical "thrifty genes"? (4) How can we cope with disease susceptibility caused by the "thrifty" SNPs? We examined mtDNA and genes for energy metabolism in people who live in several parts of Asia and the Pacific islands. We included 14 genes, and the SNP frequencies of PPAR gamma 2, LEPR, and UCP3-p and some other genes differ significantly between Mongoloids and Caucasoids. These differences in SNPs may have been caused by natural selection depending on the types of agriculture practiced in different regions. Interventions to counteract the adverse effects of "thrifty" SNPs have been partially effective.     

冬虫夏草菌3个细胞核蛋白编码基因的分子进化

【目的】分析3个细胞核蛋白编码基因(csp1、MAT1-1-1和MAT1-2-1)在不同冬虫夏草菌株间的分子进化。【方法】从125个冬虫夏草样品中分别扩增csp1、MAT1-1-1和MAT1-2-1基因序列,比较外显子和内含子间以及2个交配型基因间的序列变异程度,比较基于不同基因或基因区域所构建的系统发育树拓扑结构的差异,分析3个基因承受的选择压力和DNA重组情况。【结果】3个蛋白编码基因外显子区的长度在不同菌株间高度保守,具有4.5%?5.7%的变异位点;内含子区的长度在不同菌株间相同或不同,具有1.8%?22%的变异位点。对于2个交配型基因,MAT1-1-1的碱基变异率低于MAT1-2-1。基于外显子与内含子构建的系统发育树的拓扑结构,以及基于2个交配型基因外显子构建的系统发育树的拓扑结构都存在明显差异。3个蛋白编码基因都经历着净化选择作用。基因内部的不同DNA位点间有重组,但3个基因片段之间没有明显的重组发生。【结论】由于冬虫夏草菌不同基因以及基因的不同区域表现出进化上的差异,所以在开展冬虫夏草菌进化相关的研究时,应该联合使用多个不同的基因片段。     

Recent insights into stearoyl-CoA desaturase-1

PURPOSE OF REVIEW: Stearoyl-Coenzyme A (CoA) desaturase is a central lipogenic enzyme catalyzing the synthesis of monounsaturated fatty acids - mainly oleate (C(18:1)). Oleate is the most abundant monounsaturated fatty acid in dietary fat and is therefore readily available. Why, then, is stearoyl-CoA desaturase a highly regulated enzyme? This review summarizes the recent and timely advances concerning the important role of stearoyl-CoA desaturase in metabolism. RECENT FINDINGS: Recent findings using mice that have a naturally occurring mutation in the SCD1 gene isoform as well as a mouse model with a targeted disruption of the stearoyl-CoA desaturase gene-1 (SCD1-/-) have revealed the role of de-novo synthesized oleate and thus the physiological importance of SCD1 expression. In the highlighted references, it is shown that the SCD1-/- mice have reduced body adiposity, increased insulin sensitivity, and are resistant to diet-induced obesity. The expression of several genes of lipid oxidation is upregulated, whereas lipid synthesis genes are downregulated. SCD1 was also found to be a component of the novel metabolic response to the hormone leptin. SUMMARY: SCD1, therefore, appears to be an important metabolic control point, and inhibition of its expression could be of benefit for the treatment of obesity, diabetes and other metabolic diseases.     

Related polymorphic F-box protein genes between haplotypes clustering in the BAC contig sequences around the S-RNase of Japanese pear

Most fruit trees in the Rosaceae exhibit self-incompatibility, which is controlled by the pistil S gene, encoding a ribonuclease (S-RNase), and the pollen S gene at the S-locus. The pollen S in Prunus is an F-box protein gene (SLF/SFB) located near the S-RNase, but it has not been identified in Pyrus and Malus. In the Japanese pear, various F-box protein genes (PpSFBB(-α-γ)) linked to the S-RNase are proposed as the pollen S candidate. Two bacterial artificial chromosome (BAC) contigs around the S-RNase genes of Japanese pear were constructed, and 649?kb around S(4)-RNase and 378?kb around S(2)-RNase were sequenced. Six and 10 pollen-specific F-box protein genes (designated as PpSFBB(4-u1-u4, 4-d1-d2) and PpSFBB(2-u1-u5,) (2-d1-d5), respectively) were found, but PpSFBB(4-α-γ) and PpSFBB(2-γ) were absent. The PpSFBB(4) genes showed 66.2-93.1% amino acid identity with the PpSFBB(2) genes, which indicated clustering of related polymorphic F-box protein genes between haplotypes near the S-RNase of the Japanese pear. Phylogenetic analysis classified 36 F-box protein genes of Pyrus and Malus into two major groups (I and II), and also generated gene pairs of PpSFBB genes and PpSFBB/Malus F-box protein genes. Group I consisted of gene pairs with 76.3-94.9% identity, while group II consisted of gene pairs with higher identities (>92%) than group I. This grouping suggests that less polymorphic PpSFBB genes in group II are non-S pollen genes and that the pollen S candidates are included in the group I PpSFBB genes.     

棉蚜2个乙酰胆碱酯酶cDNA片段的基因克隆与序列分析

采用RT－PCR技术,利用简并引物从棉蚜（Aphis gossypii Glover)中克隆出2个乙酰胆碱酯酶基因的cDNA片段,Ag,ace 1l和Ag.ace2.Ag.ace1基因的cDNA片段为282bp,编码94个氨基酸;Ag.ace2基因的cDNA片段为264bp,编码88个氨基酸。扩增获得的2个乙酰胆碱酯酶基因cDNA片段所编码的氨基酸序列均与其他昆虫的乙酰胆碱酯酶基因有很高的同源性。首次从一种昆虫中克隆出2个乙酰胆碱酯酶基因片段,为同一种昆虫中存在多个乙酰胆碱酯酶基因的假设提供了直接的分子生物学证据。