Leptospirillum ferrooxidans and similar bacteria: Some characteristics and genomic diversity

Abstract Several isolates of Leptospirillum -like bacteria and Leptospirillum ferrooxidans have been examined. Different growth rates on iron, some differences in electrophoretic whole-cell protein patterns and particularly the poor DNA-DNA homology among some isolates have indicated that the binomial L. ferrooxidans is inadequate for classification of the Leptospirillum -like bacteria. However, the morphology and the mol% GC values of the isolates have indicated at least one or two groups of apparently similar bacteria, readily identifiable and distinct from Thiobacillus ferrooxidans .     

Identification of putative homology between horse microsatellite flanking sequences and cross-species ESTs, mRNAs and genomic sequences

In this study the flanking sequences of 1534 horse microsatellites were used in a BLAST search to identify putative human-horse homologies. BLAST searches revealed 129 flanking sequences with significant blastn matches [alignment scores (S) > or = 60 and sum probability values (E) < or = 3.0E-6], also, 25 of these produced significant blastx matches. To provide a reference point in the human genome the flanking sequences with matches were subjected to a BLAT search of the University of California Santa Cruz (UCSC) human genome assembly (July 2003 freeze). Eighty-three of the flanking sequences showed high similarity to sequence of known or putative human genes and the remaining 46 demonstrated high similarity to human intragenic regions. Interestingly, 87 of the microsatellites showed conservation of the tandem repeat in addition to flanking regions. Overall, 41 of the microsatellites had been mapped in the horse and of these 37 localized to the expected syntenic location. The other four did not and represent new putative regions of human-horse synteny. The results of this study contribute 79 new putative human-horse homologies, increasing the density of markers on the human-horse comparative map.     

Monotremes as Pretribosphenic Mammals

An abundance of evidence points to the conclusion that monotremes are phyletically allied with pretribosphenic, rather than with tribosphenic, mammals. Monotremes do not have a tribosphenic dentition. Character analyses that apply tribosphenic cusp terminology to monotreme dentitions are implicitly limited thereby. A review of the molar dentition of living and fossil monotremes suggests that upper molars are composed of a strongly developed pretribosphenic paracone and metacone and a series of stylar cusps attached to them in a bicrescentic, or dilambdodont, fashion. The lower molars are composed of a trigonid, with a pretribosphenic protoconid, paraconid, and metaconid, and distal metacristid. The paraconid of m1 is reduced or lost. The talonid is composed of the pretribosphenic hypoconid, hypoconulid, and cristid obliqua. There is no evidence for a tribosphenic entoconid, nor for a talonid basin. There was no tribosphenic protocone. Monotremes are not related to other taxa included in Australosphenida. The dentition of Cretaceous taxa, such as Teinolophos and Steropodon, apparently still functioned by orthal mechanisms, whereas by the medial Paleocene (Monotrematum) and later (Obdurodon), monotremes appear to have accommodated a diet of soft-bodied organisms that left little trace of a mastication regime that had changed to apical wear via propalinal motion. Monotremes appear to be modern representatives of a Mesozoic radiation of pretribosphenic mammals centered largely in Gondwana, where they still reside today.     

Homologies between nuclear and plastid DNA in spinach

Summary Homologies between spinach nuclear (n) DNA and Chloroplast (pt) DNA, have been detected with a clone bank of spinach ptDNA as hybridization probes to restriction fragments of nDNA prepared from purified root nuclei. Every cloned fragment of ptDNA showed homologies to discrete restriction fragments of nDNA, different from those of ptDNA, indicating integration of these homologies into nDNA. While most ptDNA clones were relatively large and probably contained several genes, sequence homologies were also found to the cloned plastid gene for RuBP carboxylase and the subunit of ptATPase. Many of the homologies in nDNA occur in regions of the genome that are highly methylated and are not digested by the methylation sensitive restriction endonucleases HpaII and MspI. In contrast these enzymes cleave ptDNA into small fragments which allows the nDNA homologies to be distinguished in total root DNA. The sequence homologies observed were not due to contaminating non nuclear sequences as shown by hybridization to mitochondrial (mt) and bacterial DNAs. The total amount of homology to ptDNA in nDNA is equivalent to about five copies of the plastome per haploid nuclear genome. The homologies generally appear to be in individual segments of less than 2 kbp in length, integrated into several different places in the genome.On sabbatical leave from Department of Botany, University College, Dublin, Ireland     

Homologies to chloroplast DNA in the nuclear DNA of a number of Chenopod species

Summary Sequences homologous to chloroplast (ct)DNA have been found in nuclear DNA in five species of the Chenopodiaceae, extending the earlier observations of promiscuous DNA in Spinacia oleracea (Timmis and Scott 1983). Using the 7.7 kbp spinach ctDNA Pst I fragment as a hybridization probe, several separately located homologies to ctDNA were resolved in the nuclear DNA of Beta vulgaris, Chenopodium quinoa, and Enchylaena tomentosa. In Chenopodium album and Atriplex cinerea the major region of homology was to a nuclear Eco RI fragment (6 kbp) indistinguishable from that in ctDNA. These homologies may therefore involve larger tracts of ctDNA because the same restriction sites are apparently retained in the nucleus. This suggests that in these latter two species there is a contrasting, more homogeneous arrangement of ctDNA transpositions in the nucleus.     

Development and morphology of the inverted yolk sac in the guinea pig (Cavia porcellus)

Although the guinea pig is an important animal model for human placentation, aspects of fetal nutrition are not fully understood, especially in regard to the yolk sac that is regarded to be essential for early development of the embryo. We investigated differentiation by means of histology, histochemistry, immunohistochemistry, and transmission electron microscopy. Data suggest that the guinea pig's yolk sac was not sufficiently developed to facilitate substantial fetal nutrition in early pregnancy. On Day 12, it was a flat, inverted, but avascular structure. This was followed by differentiation to form the typical, highly villous and vascularized condition of advanced gestation. Finally, the yolk sac degenerated toward term. We suggest that the guinea pig and other caviomorphs rely predominantly on hemotrophic nutrition via the placenta even in very early pregnancy. In contrast to the general pattern of mammals, histiotrophic nutrition via yolk sac routes seems to be most essential during mid-gestation.     

Homologies to plastid DNA in the nuclear and mitochondrial genomes of potato

Summary Potato plastid DNA clones, representing onefourth of the potato plastome complexity and containing sequences of the 16SrRNA, rps16, atpA, atpE, psaA, psaB, trnK, trnV, and trnG genes, were used as hybridization probes on nuclear- and mitochondrial-enriched DNAs. Each probe hybridized to multiple nuclear restriction fragments distinct from the plastid cleavage products generated by the same endonucleases. The nuclear hybridizable fragments are highly methylated at their Hpall target sequences (C/CGG). In some instances, the transfer seemed to involve plastid regions of several kilobase pairs, as reflected by the co-integration in the nucleus of restriction sites that are distant in the plastome. Three clones hybridized additionally to distinct mitochondrial fragments. These results indicate that extensive DNA transfers did occur between plastids and other organelles in potato.     

Within the twilight zone: a sensitive profile-profile comparison tool based on information theory

This paper presents a novel approach to profile-profile comparison. The method compares two input profiles (like those that are generated by PSI-BLAST) and assigns a similarity score to assess their statistical similarity. Our profile-profile comparison tool, which allows for gaps, can be used to detect weak similarities between protein families. It has also been optimized to produce alignments that are in very good agreement with structural alignments. Tests show that the profile-profile alignments are indeed highly correlated with similarities between secondary structure elements and tertiary structure. Exhaustive evaluations show that our method is significantly more sensitive in detecting distant homologies than the popular profile-based search programs PSI-BLAST and IMPALA. The relative improvement is the same order of magnitude as the improvement of PSI-BLAST relative to BLAST. Our new tool often detects similarities that fall within the twilight zone of sequence similarity.     

Supernumerary molars in anthropoidea,adapidae, and Archaeolemur: Implications for primate dental homologies

The model of primate dental homologies and development recently proposed by Schwartz ('75, '78) is re-evaluated in view of documented exceptions to his account of postcanine supernumerary teeth in both anthropoids and prosimians. Schwartz concluded that catarrhines and living indriids retain only two true molars in each dental quadrant. As many as six molars on one side of the jaw can develop in rare instances in catarrhines, and supernumerary molars are also known for a wide range of other primates, including Cebidae, Adapidae, and subfossil Indriidae. Polydontia cannot be explained exclusively by atavistic development. More convincing explanations regard supernumerary teeth as the result of excessive growth of the dental lamina or localized twinning of tooth buds during early development. Conventional dental formulae of catarrhines and indriids including three permanent molars remain the most plausible.     

Directional ligation of long-flanking homology regions to selection cassettes for efficient targeted gene-disruption in Candida albicans

PCR-product directed gene disruption with a marker cassette having short homology regions is often used in Candida albicans. However, it is quite inefficient due to the high frequency of non-homologous recombination at non-targeted loci, which necessitates extensive screening to identify the correct disruptants. Thus, many PCR-based methods to introduce long flanking homology regions have been developed to increase the frequency of integration at the targeted loci. However, these methods are not that amenable for use with the widely employed C. albicans marker cassettes having direct repeats, as these repeats tend to recombine during PCR, resulting in shorter amplified products without the selection marker. To circumvent this limitation, we have developed a dinucleotide-sticky-end-ligation strategy to add one flanking homology region to one side of the selection cassette, and the other flanking homology region to the other side of the selection cassette. This method involves release of the selection cassette from the plasmid by digestion with two different restriction enzymes, followed by partial fill-in, to provide a unique two base overhang at each end of the cassette. The flanking homology regions, corresponding to the gene to be disrupted, are individually PCR-amplified, and treated with T4-DNA Polymerase in the presence of appropriate dNTPs to yield two base-5' overhangs. The primers used for the PCR have additional bases at the 5' ends such that after T4 DNA Polymerase treatment, the two flanks will have distinct overhangs compatible with the overhangs of the partially filled-in selection cassette. The selection cassette and the flanks are then ligated together and directly used to transform C. albicans. We have successfully used this method for disruption of several C. albicans genes. We have also used this method to recreate insertion mutations obtained with transposons to reconfirm the mutant phenotypes. This approach can be extended to other organisms like Schizosaccharomyces pombe which also require long flanking regions of homology for targeted gene disruption.     

Cross-Homologies and Structural Differences Between Human Cholinesterases Revealed by Antibodies Against cDNA-Produced Human Butyrylcholinesterase Peptides

To study the polymorphism of human cholinesterases (ChEs) at the levels of primary sequence and three-dimensional structure, a fragment of human butyrylcholinesterase (BuChE) cDNA was subcloned into the pEX bacterial expression vector and its polypeptide product analyzed. Immunoblot analysis revealed that the clone-produced BuChE peptides interact specifically with antibodies against human and Torpedo acetylcholinesterase (AChE). Rabbit polyclonal antibodies prepared against the purified clone-produced BuChE polypeptides interacted in immunoblots with denatured serum BuChE as well as with purified and denatured erythrocyte AChE. In contrast, native BuChE tetramers from human serum, but not AChE dimers from erythrocytes, interacted with these antibodies in solution to produce antibody-enzyme complexes that could be precipitated by second antibodies and that sedimented faster than the native enzyme in sucrose gradient centrifugation. Furthermore, both AChE and BuChE dimers from muscle extracts, but not BuChE tetramers from muscle, interacted with these antibodies. To reveal further whether the anti-cloned BuChE antibodies would interact in situ with ChEs in the neuromuscular junction, bundles of muscle fibers were microscopically dissected from the region in fetal human diaphragm that is innervated by the phrenic nerve. Muscle fibers incubated with the antibodies and with 125I-Protein A were subjected to emulsion autoradiography, followed by cytochemical ChE staining. The anti-cloned BuChE antibodies, as well as anti-Torpedo AChE antibodies, created patches of silver grains in the muscle endplate region stained for ChE, under conditions where control sera did not. These findings demonstrate that the various forms of human AChE and BuChE in blood and in neuromuscular junctions share sequence homologies, but also display structural differences between distinct molecular forms within particular tissues, as well as between similarly sedimenting molecular forms from different tissues.     

Ribosomal RNA homologies and the evolution of the filamentous blue-green bacteria

Summary Ribosomal RNA (rRNA) sequence homology (as determined by comparisons of T1 oligonucleotide catalogs of³²P-labeled 16S rRNAs) has been used to assess phylogenetic relationships within the filamentous and unicellular blue-green bacteria, and to identify regions of evolutionary conservatism within blue-green bacterial 16S rRNAs.Nostoc andFischerella, representatives of two morphologically distinct and highly differentiated orders, are shown to be as closely related (on the basis of RNA sequence homology) as typical members of the non-blue-green bacterial genusBacillus. They are further shown to be (on the same basis) indistinguishable from typical unicellular members of a subgroup of the unicellular blue-green bacterial order Chroococcales. These results have general implications for studies of the origin of differentiated prokaryotes and of evolutionary change in prokaryotic macromolecules. In particular, they provide indirect evidence that the divergences of contemporary major prokaryotic groups are truly ancient ones.     

tRNA-rRNA sequence homologies: evidence for an ancient modular format shared by tRNAs and rRNAs

Homologies between tRNAs and rRNAs are identified in searches using various combinations of Escherichia coli, yeast, Halobacterium volcanii and bovine mitochondrial sequences. As in previously reported comparisons, the homologies are too frequent and long to be attributed to coincidence, and similar frequencies from inter- and intraspecies comparisons preclude evolutionary convergence as an explanation. In contrast to the earlier studies, patterns in the positioning of the homologies are now described. Graphing the positions of the homologies along orthogonal axes that represent numbers of bases in tRNA and rRNA shows recurring patterns in the alignments. Preferred spacings of integral multiples of 9 bases are found, suggesting a periodicity in the ancestral structure from which the tRNAs and rRNAs were derived. The periodicity also suggests persistence of a modular format in both classes of molecules that survived changes in sequence that occurred during evolution. A model is proposed for the generation of the ancestral molecule and the early evolution of the coding mechanism. Elongation by self-priming and self-templating gave a hairpin with a 9 base stem. Two additional cycles gave a 70-80 base tRNA-like structure. Additional cycles yielded a tandem repeat of this unit, roughly equivalent in size to the combined rRNAs of prokaryotes. The larger RNA would contain the information and materials for generating the smaller RNAs. It is proposed that multiple recombination among such molecules gave composite structures, presumed progenitors of today's t- and rRNAs. The distribution of the conserved domains among today's species argues for the existence of the ancestral molecule prior to divergence of lines leading to the various kingdoms. Their presence in the different nucleic acids suggests the existence of a nucleic acid with multiple functions prior to partitioning of these functions among the nucleic acids that exist today. The occurrence of overlaps, overlays and consensus alignments among the homologies provides the means for identifying contiguous and neighboring conserved regions and holds promise for the reconstruction of the sequence of an ancestral molecule.