Mechanism of activation of human heparanase investigated by protein engineering

The aim of this study was to investigate the mechanism of activation of human heparanase, a key player in heparan sulfate degradation, thought to be involved in normal and pathologic cell migration processes. Active heparanase arises as a product of a series of proteolytic processing events. Upon removal of the signal peptide, the resulting, poorly active 65 kDa species undergoes the excision of an intervening 6 kDa fragment generating an 8 kDa polypeptide and a 50 kDa polypeptide, forming the fully active heterodimer. By engineering of tobacco etch virus protease cleavage sites at the N- and C-terminal junctions of the 6 kDa fragment, we were able to reproduce the proteolytic activation of heparanase in vitro using purified components, showing that cleavage at both sites leads to activation in the absence of additional factors. On the basis of multiple-sequence alignment of the N-terminal fragment, we conclude that the first beta/alpha/beta element of the postulated TIM barrel fold is contributed by the 8 kDa subunit and that the excised 6 kDa fragment connects the second beta-strand and the second alpha-helix of the barrel. Substituting the 6 kDa fragment with the topologically equivalent loop from Hirudinaria manillensis hyaluronidase or connecting the 8 and 50 kDa fragments with a spacer of three glycine-serine pairs resulted in constitutively active, single-chain heparanases which were comparable to the processed, heterodimeric enzyme with regard to specific activity, chromatographic profile of hydrolysis products, complete inhibition at NaCl concentrations above 600 mM, a pH optimum of pH approximately 5, and inhibition by heparin with IC(50)s of 0.9-1.5 ng/microL. We conclude that (1) the heparanase heterodimer (alpha/beta)(8)-TIM barrel fold is contributed by both 8 and 50 kDa subunits with the 6 kDa connecting fragment leading to inhibition of heparanase by possibly obstructing access to the active site, (2) proteolytic excision of the 6 kDa fragment is necessary and sufficient for heparanase activation, and (3) our findings open the way to the production of recombinant, constitutively active single-chain heparanase for structural studies and for the identification of inhibitors.     

Production of ramoplanin analogues by genetic engineering of Actinoplanes sp.

Ramoplanins are lipopeptides effective against a wide range of Gram-positive pathogens. Ramoplanin A2 is in Phase III clinical trials. The structure–activity relationship of the unique 2Z,4E-fatty acid side-chain of ramoplanins indicates a significant contribution to the antimicrobial activities but ramoplanin derivatives with longer 2Z,4E-fatty acid side-chains are not easy to obtain by semi-synthetic approaches. To construct a strain that produces such analogues, an acyl-CoA ligase gene in a ramoplanin-producing Actinoplanes was inactivated and a heterologous gene from an enduracidin producer (Streptomyces fungicidicus) was introduced into the mutant. The resulting strain produced three ramoplanin analogues with longer alkyl chains, in which X1 was purified. The MIC value of X1 was ~0.12 μg/ml against Entrococcus sp. and was also active against vancomycin-resistant Staphylococcus aureus (MIC = 2 μg/ml).     

Lignin genetic engineering

Although lignins play important roles in plants, they often represent an obstacle to the utilization of plant biomass in different areas: pulp industry, forage digestibility. The recent characterization of different lignification genes has stimulated research programmes aimed at modifying the lignin profiles of plants through genetic engineering (antisense and sense suppression of gene expression). The first transgenic plants with a modification of monomeric composition of lignins and lignin content have been recently obtained. Down regulation of the OMT gene induces dramatic reduction of syringyl units. CAD down regulated plants exhibit a unusual red phenotype associated with the developing xylem and several chemical modifications of their lignins including an increase in cinnamaldehydes in the polymer structure. Interestingly this novel lignin is removed more easily during the pulping process. In both OMT and CAD down regulated plants no changes in phenotypic characteristics such as growth architecture and morphology were observed. More recent experiments have shown that a reduction of CCR activity determines specific changes in the coloration of the xylem area suggesting significant chemical modifications which are currently being studied.These different results show that it is possible to manipulate lignins through targeted genetic transformation of plants and that lignins exhibit a relative flexibility of their chemical structure. Future developments should probe the impact of down regulating the expression of other recently characterized lignification genes such as F5H and CCoAOMT and also of a combination of genes in order to tailor lignins more adapted to specific purposes. In addition to biotechnological applications which should provide important economical benefits for utilization of wood in the pulp industry, genetic engineering of lignins offer very promising perspectives for the understanding of lignin synthesis, structure and properties.     

Mammalian cell culture: engineering principles and scale-up

If biological products such as monoclonal antibodies, interferons, vaccines, plasminogen activators and many others are to be obtained at an economic cost from mammalian cells, a number of engineering problems must be solved (Tables 1 and 2). The two most imposing barriers to the scale-up of this technology from those listed are the inability to provide sufficient oxygen to high density cultures of mammalian cells grown in large volumes, and the high cost of serum usage. This review focuses on: (i) techniques used to cultivate mammalian cells; (ii) technical barriers to scale-up; and (iii) comparing methods of producing cells with regards to their ability to overcome these barriers.     

Prospects for the genetic engineering of milk.

Milk and milk products comprise a substantial fraction of the protein intake of the industrialised West. The establishment of germline manipulation techniques in cows offers opportunities for directly manipulating milk composition to produce products with enhanced nutritional and processing properties. The major milk proteins are encoded by a small number of abundantly expressed single-copy genes and a number of possible manipulations are described. Milk proteins exhibit complex interactions with each other and with other constituents of milk. It will, therefore, be necessary to utilise model systems to evaluate the consequences of these proposed changes before embarking upon the costly and time-consuming process of manipulating the bovine genome.     

Improving plant genetic engineering by manipulating the host

Agrobacterium-mediated transformation is a major technique for the genetic engineering of plants. However, there are many economically important crop and tree species that remain highly recalcitrant to Agrobacterium infection. Although attempts have been made to "improve" transformation by altering the bacterium, future successes might come from manipulation of the plant. Recent studies that identified several plant genes involved in Agrobacterium-mediated transformation, and their over-expression in currently transformable species, suggest that this approach holds great promise for improving the transformation of recalcitrant, but agronomically important, crops.     

Improvement of wool production through genetic engineering.

Wool is a natural fibre popular in the manufacture of outer clothing and is a vital source of income for several countries. Fundamental knowledge of how wool grows has been gained from research on the biology of sheep, and the prospects ahead are to take advantage of the development and application of recombinant DNA technology to improve the efficiency of production of wool and its quality. This review surveys the possibilities for producing transgenic sheep, modifying rumen bacteria and forage crops, thus increasing the nutritional benefit sheep gain from pasture.     

Inter- and intraspecific genetic variation inHippophae (Elaeagnaceae) investigated by RAPD markers

Genetic diversity has been investigated by the application of molecular markers in, for the first time, all the taxa recognised in recent treatises of the genusHippophae. RAPD (random amplified polymorphic DNA) analyses were conducted with 9 decamer primers, which together yielded 219 polymorphic markers. We found 16 fixed RAPD markers, i.e. markers that either occurred in all plants of a population or were absent from all plants. Several of these markers were useful for analysis of interspecific relationships, whereas others can be considered as taxon-specific markers. Clustering of taxa and populations in our neighbour-joining based dendrogram was in good agreement with some recently suggested taxonomic treatises ofHippophae. Amount and distribution of genetic variability varied considerably between species. Partitioning of molecular variance withinH. rhamnoides supported earlier findings that a considerable part of the total variance resides among subspecies (59.6%) Within-population variability also differed considerably. Percentage polymorphic RAPD loci and Lynch and Milligan within-population gene diversity estimates showed relatively high values for some species close to the geographic centre of origin in Central Asia, e.g.H. tibetana and the putatively hybridogenousH. goniocarpa. Spatial autocorrelation analyses performed on 12 populations ofH. rhamnoides revealed positive autocorrelation of allele frequencies when geographic distances ranged from 0 to 700 km, and no or negative autocorrelation at higher distances. At distances between 700 and 1900 km, we observed deviations from the expected values with strongly negative autocorrelation of allele frequencies. A corresponding relationship between geographic and genetic distances could not be found when the analysis instead was based on one population from each of 8 species.     

Measuring genetic stability in bacteria of potential use in genetic engineering.

Four commonly used conjugation techniques, colony cross streak (CCS), broth mating (BM), combined spread plate (CSP), and membrane filtration (MF), were compared with each other regarding reliability, sensitivity, and complexity in evaluating the transfer of conjugative plasmids. Five plasmids representing several incompatibility groups plus a variety of laboratory and environmental isolates were used as mating pairs. The suitability of each method was evaluated for use in a routine assessment of the genetic stability of genetically engineered microorganisms. By the CSP and MF techniques with laboratory strains such as Escherichia coli and Pseudomonas species as recipients, transconjugants were usually produced in 100% of the mating trials. However, when environmental strains isolated from plants and soil were used as recipients, transconjugants were detected in 100% of some crosses and in as little as 30% in other crosses depending on the plasmid and recipient used. In general, differences in the percentage of successful matings between the CSP and MF techniques compared with the BM and CCS techniques were not statistically significant at the P less than or equal to 0.05 level. Occasionally, certain mating pairs consistently produced transconjugants by CCS or BM but not by CSP or MF. Since any single conjugation mating technique is not completely reliable in detecting transconjugants, we have developed a combined mating technique which integrates the CCS, CSP, BM, and MF methods as a single procedure to assess the mobility of plasmid DNA of genetically engineered microorganisms.     

Citrus phylogeny and genetic origin of important species as investigated by molecular markers

Citrus phylogeny was investigated using RAPD, SCAR and cpDNA markers. The genotypes analyzed included 36 accessions belonging to Citrus together with 1 accession from each of the related genera Poncirus, Fortunella, Microcitrus and Eremocitrus. Phylogenetic analysis with 262 RAPDs and 14 SCARs indicated that Fortunella is phylogenetically close to Citrus while the other three related genera are distant from Citrus and from each other. Within Citrus, the separation into two subgenera, Citrus and Papeda, designated by Swingle, was clearly observed except for C. celebica and C. indica. Almost all the accessions belonging to subgenus Citrus fell into three clusters, each including 1 genotype that was considered to be a true species. Different phylogenetic relationships were revealed with cpDNA data. Citrus genotypes were separated into subgenera Archicitrus and Metacitrus, as proposed by Tanaka, while the division of subgenera Citrus and Papeda disappeared. C. medica and C. indica were quite distant from other citrus as well from related genera. C. ichangensis appeared to be the ancestor of the mandarin cluster, including C. tachibana. Lemon and Palestine sweet lime were clustered into the Pummelo cluster led by C. latipes. C. aurantifolia was located in the Micrantha cluster. Furthermore, genetic origin was studied on 17 cultivated citrus genotypes by the same molecular markers, and a hybrid origin was hypothesized for all the tested genotypes. The assumptions are discussed with respect to previous studies; similar results were obtained for the origin of orange and grapefruit. Hybrids of citron and sour orange were assumed for lemon, Palestine sweet lime, bergamot and Volkamer lemon, while a citron × mandarin hybrid was assumed for Rangpur lime and Rough lemon. For Mexican lime our molecular data indicated C. micrantha to be the female parent and C. medica as the male one. Received: 5 October 1999 / Accepted: 3 November 1999     

Impaired spermatogenesis in the finch hybrid L. castaneothorax by L. punctulata: Transmission electron microscopy and genetic analysis

As part of a project to determine whether there is any correlation between the form of hybrid sterility and the genetic relatedness of the parental species, we studied a male intrageneric hybrid between two finch species (Lonchura custaneothorax × L. punctuluta), and compared the ultrastructural basis of hybrid sterility in this species with that reported by Swan [1985] for an intergeneric bird hybrid. In the latter study the sterility appeared to have an autoimmune basis, due to lack of Sertoli-Sertoli tight junctions. In the hybrid examined in the present study, lanthanum tracing showed that the junctions were tight. There was no testicular immune reaction; the parental species were almost identical in chromosomal constitution, having only a small inversion difference on chromosome 5, and only two structural protein differences could be detected through examination of the variation at 38 protein loci. Nevertheless, the hybrid appeared sterile and had the following ultrastructural testicular features. Intercellular bridges where present were usually abnormal in structure; centrioles in a centriole pair were arranged in parallel. Many spermatocytes and spermatids degenerated and were phagocytosed by Sertoli cells. Some spermatids progressed to mature testicular spermatozoa in sperm bundles, but commonly had multiple (2–4) axonemes or disrupted doublets and accessory fibers. The multiple axonemes present in most spermatids inserted separately into the base of the nucleus and the multiple centrioles were capable of organizing separate neck structures. We conclude that these cytological abnormalities were caused by genic effects and discuss why they appeared to be restricted to the germ line.     

Mammalian small nucleolar RNAs are mobile genetic elements

Small nucleolar RNAs (snoRNAs) of the H/ACA box and C/D box categories guide the pseudouridylation and the 2'-O-ribose methylation of ribosomal RNAs by forming short duplexes with their target. Similarly, small Cajal body-specific RNAs (scaRNAs) guide modifications of spliceosomal RNAs. The vast majority of vertebrate sno/scaRNAs are located in introns of genes transcribed by RNA polymerase II and processed by exonucleolytic trimming after splicing. A bioinformatic search for orthologues of human sno/scaRNAs in sequenced mammalian genomes reveals the presence of species- or lineage-specific sno/scaRNA retroposons (sno/scaRTs) characterized by an A-rich tail and an approximately 14-bp target site duplication that corresponds to their insertion site, as determined by interspecific genomic alignments. Three classes of snoRTs are defined based on the extent of intron and exon sequences from the snoRNA parental host gene they contain. SnoRTs frequently insert in gene introns in the sense orientation at genomic hot spots shared with other genetic mobile elements. Previously characterized human snoRNAs are encoded in retroposons whose parental copies can be identified by phylogenic analysis, showing that snoRTs can be faithfully processed. These results identify snoRNAs as a new family of mobile genetic elements. The insertion of new snoRNA copies might constitute a safeguard mechanism by which the biological activity of snoRNAs is maintained in spite of the risk of mutations in the parental copy. I furthermore propose that retroposition followed by genetic drift is a mechanism that increased snoRNA diversity during vertebrate evolution to eventually acquire new RNA-modification functions.     

Mammalian cell function mediating recombination of genetic elements

Recombination of segments of the SV40 genome by a variety of mechanisms is described. These include the faithful joining of linear segments that have flush termini as opposed to previously described cohesive or resected termini. Lack of involvement of viral proteins has been demonstrated for recombination of segments with homologous overlapping termini, but probably applies also to the other joining reactions. Segments of the genome that have been cleaved in such a manner as to be unable to manufacture any known viral proteins are neutral elements of genetic information, incapable of selection by replication or biological function until recombined. These recombination functions presumably are available to the host cell and any element of genetic information that can be generated in that cell.