Dynamic genome plasticity during unisexual reproduction in the human fungal pathogen Cryptococcus deneoformans

Genome copy number variation occurs during each mitotic and meiotic cycle and it is crucial for organisms to maintain their natural ploidy. Defects in ploidy transitions can lead to chromosome instability, which is a hallmark of cancer. Ploidy in the haploid human fungal pathogen Cryptococcus neoformans is exquisitely orchestrated and ranges from haploid to polyploid during sexual development and under various environmental and host conditions. However, the mechanisms controlling these ploidy transitions are largely unknown. During C. deneoformans (formerly C. neoformans var. neoformans, serotype D) unisexual reproduction, ploidy increases prior to the onset of meiosis, can be independent from cell-cell fusion and nuclear fusion, and likely occurs through an endoreplication pathway. To elucidate the molecular mechanisms underlying this ploidy transition, we identified twenty cell cycle-regulating genes encoding cyclins, cyclin-dependent kinases (CDK), and CDK regulators. We characterized four cyclin genes and two CDK regulator genes that were differentially expressed during unisexual reproduction and contributed to diploidization. To detect ploidy transition events, we generated a ploidy reporter, called NURAT, which can detect copy number increases via double selection for nourseothricin-resistant, uracil-prototrophic cells. Utilizing this ploidy reporter, we showed that ploidy transition from haploid to diploid can be detected during the early phases of unisexual reproduction. Interestingly, selection for the NURAT reporter revealed several instances of segmental aneuploidy of multiple chromosomes, which conferred azole resistance in some isolates. These findings provide further evidence of ploidy plasticity in fungi with significant biological and public health implications.     

Mechanistic studies on aggregation of polyethylenimine-DNA complexes and its prevention

Aggregation of polyethylenimine (PEI)-DNA complexes severely undermines their utility for gene delivery into mammalian cells. Herein we undertook to elucidate the mechanism of this deleterious phenomenon and to develop rational strategies for its prevention. The effect of temperature, surfactants, complex concentration, ionic strength, viscosity, and pH on the time course of this aggregation was systematically examined. The aggregation process was completely inhibited by 2.5% polyoxyethylene (100) stearate (POES) and to a lesser degree by other nonionic surfactants. Importantly, POES preserved the transfection efficiency of the complexes without inducing toxicity. The aggregation was also reduced by lowering the temperature and pH, diluting the complexes, and increasing the solution viscosity. It is concluded that PEI-DNA complexes aggregate primarily due to hydrophobic interactions, while electrostatic attractions play little role.     

Crystal structure of the complex of the secretory phospholipase A2 from Daboia russelli pulchella with an endogenic indole derivative, 2-carbamoylmethyl-5-propyl-octahydro-indol-7-yl-acetic acid at 1.8 A resolution

Phospholipase A2 (PLA2) enzymes from snake venoms are approximately 14 kDa secretory proteins and catalyze the release of arachidonic acid which is the precursor of proinflammatory mediators such as prostaglandins, leukotrienes, thromboxanes and platelet-activating factors. The structure of the PLA2 enzyme purified from the venom of Daboia russelli pulchella was determined using molecular replacement method and refined to an R value of 18.3% for all the reflections to 1.8 A resolution. The structure contains two crystallographically independent molecules A and B which form an asymmetric homodimer. The Ca2+ ion was not detected in the present structure, however, a characteristic non-protein high quality electron density was observed at the substrate-binding site of molecule A which allowed a clear interpretation of a natural ligand identified as a derivative of indole, 2-carbamoylmethyl-5-propyl-octahydro-indol-7-yl)-acetic acid. The corresponding substrate-binding site in molecule B was empty. The ligand present in molecule A is involved in extensive interactions with the protein atoms including important catalytic residues such as Asp-49 and His-48. The results also show that the indole derivatives act as potent inhibitors of secretory group II PLA2 enzymes that can be further modified to be used as potential therapeutic agents.     

Cloning of partial putative gonadotropin hormone receptor sequence from fish

A search for the presence of mariner-like elements in the Labeo rohita genome by polymerase chain reaction led to the amplification of a partial DNA sequence coding for a putative transmembrane domain of gonadotropin hormone receptor. The amplified DNA sequence shows a high degree of homology to the available turkey and human luteinizing and follicle stimulating hormone receptor coding sequences. This is the first report on cloning such sequences of piscine origin.     

The strength of receptor signaling is centrally controlled through a cooperative loop between Ca2+ and an oxidant signal

Activation of cell-surface receptors stimulates generation of intracellular signals that, in turn, direct the cellular response. However, mechanisms that ensure combinatorial control of these signaling events are not well understood. We show here that the Ca2+ and reactive oxygen intermediates generated upon BCR activation rapidly engage in a cooperative interaction that acts in a feedback manner to amplify the early signal generated. This cooperativity acts by regulating the concentration of the oxidant produced. The latter exerts its influence through a pulsed inactivation of receptor-coupled phosphatases, where the amplitude of this pulse is determined by oxidant concentration. The extent of phosphatase inhibition, in turn, dictates what proportion of receptor-proximal kinases are activated and, as a result, the net strength of the initial signal. It is the strength of this initial signal that finally determines the eventual duration of BCR signaling and the rate of its transmission through downstream pathways.     

Mutation analysis of hMSH2 and hMLH1 in colorectal cancer patients in India

The aim of this work was to study the mutation profile in hMSH2 and hMLH1 genes in hereditary nonpolyposis colorectal cancer (HNPCC) patients in India. On the basis of the Bethesda criteria, 31 colorectal cancer patients were studied first for microsatellite instability, using the five markers recommended by the Bethesda guidelines. Twelve of 31 tumor samples were found to be MSI-H, 9 of 31 were MSI-L, and the rest were MSS. The 12 patients with MSI-H were analyzed for mutations in hMSH2 and hMLH1 genes using PCR-denaturing high-performance liquid chromatography (dHPLC), followed by sequencing of samples showing abnormal peaks. Of the five mutations detected, three were found to be deleterious mutations (hMSH2-R680X, hMLH1-E671X, and a splice junction mutation IVS16-2A --> G); one had a mutation of probable significance (hMLH1-C680G) and one was of unknown significance (hMSH2-R171K). This study has also shown that most of the early-onset colon (4/7) and early-onset rectal (15/21) cancers are MSS or MSI-L. This is the first study to describe the mutation in hMSH2 and hMLH1 in Indian patients, a low incidence region for colorectal cancer. A two-stage procedure using MSI testing followed by PCR-dHPLC was found to be an efficient method in studying the mutation profile in high-risk patients.     

The number of recombination events in a sample history: conflict graph and lower bounds

We consider the following problem: Given a set of binary sequences, determine lower bounds on the minimum number of recombinations required to explain the history of the sample, under the infinite-sites model of mutation. The problem has implications for finding recombination hotspots and for the Ancestral Recombination Graph reconstruction problem. Hudson and Kaplan gave a lower bound based on the four-gamete test. In practice, their bound R/sub m/ often greatly underestimates the minimum number of recombinations. The problem was recently revisited by Myers and Griffiths, who introduced two new lower bounds R/sub h/ and R/sub s/ which are provably better, and also yield good bounds in practice. However, the worst-case complexities of their procedures for computing R/sub h/ and R/sub s/ are exponential and super-exponential, respectively. In this paper, we show that the number of nontrivial connected components, R/sub c/, in the conflict graph for a given set of sequences, computable in time 0(nm/sup 2/), is also a lower bound on the minimum number of recombination events. We show that in many cases, R/sub c/ is a better bound than R/sub h/. The conflict graph was used by Gusfield et al. to obtain a polynomial time algorithm for the galled tree problem, which is a special case of the Ancestral Recombination Graph (ARG) reconstruction problem. Our results also offer some insight into the structural properties of this graph and are of interest for the general Ancestral Recombination Graph reconstruction problem.     

Structural basis of phospholipase A2 inhibition for the synthesis of prostaglandins by the plant alkaloid aristolochic acid from a 1.7 A crystal structure

This is the first structural observation of a plant product showing high affinity for phospholipase A(2) and regulating the synthesis of arachidonic acid, an intermediate in the production of prostaglandins. The crystal structure of a complex formed between Vipera russelli phospholipase A(2) and a plant alkaloid aristolochic acid has been determined and refined to 1.7 A resolution. The structure contains two crystallographically independent molecules of phospholipase A(2) in the form of an asymmetric dimer with one molecule of aristolochic acid bound to one of them specifically. The most significant differences introduced by asymmetric molecular association in the structures of two molecules pertain to the conformations of their calcium binding loops, beta-wings, and the C-terminal regions. These differences are associated with a unique conformational behavior of Trp(31). Trp(31) is located at the entrance of the characteristic hydrophobic channel which works as a passage to the active site residues in the enzyme. In the case of molecule A, Trp(31) is found at the interface of two molecules and it forms a number of hydrophobic interactions with the residues of molecule B. Consequently, it is pulled outwardly, leaving the mouth of the hydrophobic channel wide open. On the other hand, Trp(31) in molecule B is exposed to the surface and moves inwardly due to the polar environment on the molecular surface, thus narrowing the opening of the hydrophobic channel. As a result, the aristolochic acid is bound to molecule A only while the binding site of molecule B is empty. It is noteworthy that the most critical interactions in the binding of aristolochic acid are provided by its OH group which forms two hydrogen bonds, one each with His(48) and Asp(49).