A high-resolution map of synteny disruptions in gibbon and human genomes

Gibbons are part of the same superfamily (Hominoidea) as humans and great apes, but their karyotype has diverged faster from the common hominoid ancestor. At least 24 major chromosome rearrangements are required to convert the presumed ancestral karyotype of gibbons into that of the hominoid ancestor. Up to 28 additional rearrangements distinguish the various living species from the common gibbon ancestor. Using the northern white-cheeked gibbon (2n = 52) (Nomascus leucogenys leucogenys) as a model, we created a high-resolution map of the homologous regions between the gibbon and human. The positions of 100 synteny breakpoints relative to the assembled human genome were determined at a resolution of about 200 kb. Interestingly, 46% of the gibbon–human synteny breakpoints occur in regions that correspond to segmental duplications in the human lineage, indicating a common source of plasticity leading to a different outcome in the two species. Additionally, the full sequences of 11 gibbon BACs spanning evolutionary breakpoints reveal either segmental duplications or interspersed repeats at the exact breakpoint locations. No specific sequence element appears to be common among independent rearrangements. We speculate that the extraordinarily high level of rearrangements seen in gibbons may be due to factors that increase the incidence of chromosome breakage or fixation of the derivative chromosomes in a homozygous state.     

Critical role of transmembrane segment zinc binding in the structure and function of rhodopsin

Zinc deficiency and retinitis pigmentosa are both important factors resulting in retinal dysfunction and night blindness. In this study, we address the critical biochemical and structural relevance of zinc ions in rhodopsin and examine whether zinc deficiency can lead to rhodopsin dysfunction. We report the identification of a high-affinity zinc coordination site within the transmembrane domain of rhodopsin, coordinated by the side chains of two highly conserved residues, Glu(122) in transmembrane helix III and His(211) in transmembrane helix V. We also demonstrate that this zinc coordination is critical for rhodopsin folding, 11-cis-retinal binding, and the stability of the chromophore-receptor interaction, defects of which are observed in retinitis pigmentosa. Furthermore, a cluster of retinitis pigmentosa mutations is localized within and around this zinc binding site. Based on these studies, we believe that improvement in zinc binding to rhodopsin at this site within the transmembrane domain may be a pharmacological approach for the treatment of select retinitis pigmentosa mutations. Transmembrane coordination of zinc may also be an important common principle across G-protein-coupled receptors.     

Intracellular localization of VDAC proteins in plants

Voltage-dependent anion channels (VDACs) are porin-type -barrel diffusion pores. They are prominent in the outer membrane of mitochondria and facilitate metabolite exchange between the organelle and the cytosol. Here we studied the subcellular distribution of a plant VDAC-like protein between plastids and mitochondria in green and non-green tissue. Using in vitro studies of dual-import into mitochondria and chloroplasts as well as transient expression of fluorescence-labeled polypeptides, it could be clearly demonstrated that this VDAC isoform targets exclusively to mitochondria and not to plastids. Our results support the idea that plastids evolved a concept of solute exchange with the cytosol different from that of mitochondria.Abbreviations AOX Alternative oxidase - p Precursor form - POM36 Putative outer mitochondrial membrane proteins of 36 kDa - SSU Small subunit of ribulose-1,5-bisphosphate carboxylase-oxygenase (Rubisco) - VDAC Voltage-dependent anion channel     

Retinitis pigmentosa rhodopsin mutations L125R and A164V perturb critical interhelical interactions: new insights through compensatory mutations and crystal structure analysis

L125R, a severe retinitis pigmentosa rhodopsin missense mutation, results in rhodopsin protein misfolding, retinal degeneration, and ultimately blindness. The initiating structural events leading to this protein misfolding are unknown. Through the use of compensatory mutations, in conjunction with crystal structure-based molecular analysis, we established that the larger and positively charged Arg replacing Leu125 sterically hinders both the adjacent Trp126 and a critical interhelical interaction between transmembrane III (TM III) and transmembrane V (TM V; Glu122 and His211 salt bridge). Further, analysis of another retinitis pigmentosa mutation, A164V (TM IV), indicates that the larger Val interferes with residues Leu119 and Ile123 on TM III, leading to the disruption of the same critical Glu122-His211 salt bridge (TM III-TM V interaction). Combined, these localized defects in interhelical interactions cause structural changes that interfere with the ability of opsin to bind 11-cis-retinal. These distortions ultimately lead to the formation of an abnormal disulfide bond, severe protein instability, aggregation, and endoplasmic reticulum retention. In the absence of a crystal or NMR structure of each retinitis pigmentosa mutation, compensatory mutagenesis and crystal structure-based analysis are powerful tools in determining the localized molecular disturbances. A detailed understanding of the initiating local perturbations created by missense mutations such as these, not only identifies critical factors required for correct folding and stability, but additionally opens avenues for rational drug design, mimicking the compensatory mutations and stabilizing the protein.     

Another view of T cell antigen recognition: cooperative engagement of glycolipid antigens by Va14Ja18 natural T(iNKT) cell receptor [corrected

Va14Ja18 natural T (iNKT) cells rapidly elicit a robust effector response to different glycolipid Ags, with distinct functional outcomes. Biochemical parameters controlling iNKT cell function are partly defined. However, the impact of iNKT cell receptor beta-chain repertoire and how alpha-galactosylceramide (alpha-GalCer) analogues induce distinct functional responses have remained elusive. Using altered glycolipid ligands, we discovered that the Vb repertoire of iNKT cells impacts recognition and Ag avidity, and that stimulation with suboptimal avidity Ag results in preferential expansion of high-affinity iNKT cells. iNKT cell proliferation and cytokine secretion, which correlate with iNKT cell receptor down-regulation, are induced within narrow biochemical thresholds. Multimers of CD1d1-alphaGalCer- and alphaGalCer analogue-loaded complexes demonstrate cooperative engagement of the Va14Ja18 iNKT cell receptor whose structure and/or organization appear distinct from conventional alphabeta TCR. Our findings demonstrate that iNKT cell functions are controlled by affinity thresholds for glycolipid Ags and reveal a novel property of their Ag receptor apparatus that may have an important role in iNKT cell activation.     

Immunoregulatory role of CD1d in the hydrocarbon oil-induced model of lupus nephritis

Systemic lupus erythematosus (SLE) is a systemic autoimmune disease that is accompanied by the emergence of autoreactive T cells and a reduction in regulatory T cells. Humans and mice with SLE have reduced numbers of CD1d-restricted NK T cells, suggesting a role for these cells in the regulation of SLE. In this study, we show that CD1d deficiency exacerbates lupus nephritis induced by the hydrocarbon oil pristane. This exacerbation in disease is associated with: 1) reduced TNF-alpha and IL-4 production by T cells, especially during the disease induction phase; and 2) expansion of marginal zone B cells. Strikingly, inoculation of pristane in wild-type mice resulted in reduced numbers and/or functions of NK T cells and CD1d-expressing dendritic cells. These findings suggest that CD1d may play an immunoregulatory role in the development of lupus in the pristane-induced model.     

The expression of two engrailed-related genes in an apterygote insect and a phylogenetic analysis of insect engrailed-related genes

 Homologues of the Drosophila segment polarity gene engrailed have been cloned from many insect species, as well as other arthropods and non-arthropods. We have cloned partial cDNAs of two engrailed homologues, which we call engrailed-related genes, from the phylogenetically basal insect, Thermobia domestica (Order Thysanura) and possibly as many as four engrailed-related genes from the phylogenetically intermediate insect, Oncopeltus fasciatus (Order Hemiptera). Previous to our findings, only single engrailed-related homologues had been found in phylogenetically intermediate insect species (Tribolium and Schistocerca) and in the crustacean Artemia, while two engrailed-related homologues have been found in more derived orders (Hymenoptera and the engrailed and invected genes of lepidopterans and dipterans). Consequently, we performed a phylogenetic analysis of insect engrailed-related genes to determine whether insects ancestrally had one or two engrailed-related genes. We have found evidence of concerted evolution among engrailed-related paralogues, however, that masks the true phylogenetic history of these genes; the phylogeny may only be decipherable, therefore, by examining the presence or absence of engrailed-specific and invected-specific motifs, which will require cloning the full length cDNAs from more species. In addition, we examined the embryonic expression pattern of the two Thermobia engrailed-related genes; like Drosophila engrailed and invected, they are expressed in very similar patterns, but show one temporal difference in pregnathal segments that correlates with the tentative phylogenetic placement of the genes. Thermobia engrailed-related expression also confirms that the dorsal ridge is an ancient structure in insects. Received: 4 May 1998 / Accepted: 2 August 1998     

Discovering simple DNA sequences by the algorithmic significance method

A new method, ‘algorithmic significance’, is proposedas a tool for discovery of patterns in DNA sequences. The mainidea is that patterns can be discovered by finding ways to encodethe observed data concisely. In this sense, the method can beviewed as a formal version of the Occam's Razor principle. Inthis paper the method is applied to discover significantly simpleDNA sequences. We define DNA sequences to be simple if theycontain repeated occurrences of certain ‘words’and thus can be encoded in a small number of bits. Such definitionincludes minisatellites and microsatellites. A standard dynamicprogramming algorithm for data compression is applied to computethe minimal encoding lengths of sequences in linear time. Anelectronic mail server for identification of simple sequencesbased on the proposed method has been installed at the Internetaddress pythia@anl.gov.