Mound-cell movement and morphogenesis in Dictyostelium.

To examine the mechanisms of cell locomotion within a three-dimensional (3-D) cell mass, we have undertaken a systematic 3-D analysis of individual cell movements in the Dictyostelium mound, the first 3-D structure to form during development of the fruiting body. We used time-lapse deconvolution microscopy to examine two strains whose motion represents endpoints on the spectrum of motile behaviors that we have observed in mounds. In AX-2 mounds, cell motion is slow and trajectories are a combination of random and radial, compared to KAX-3, in which motion is fivefold faster and most trajectories are rotational. Although radial or rotational motion was correlated with the optical-density wave patterns present in each strain, we also found small but significant subpopulations of cells that moved differently from the majority, demonstrating that optical-density waves are at best insufficient to explain all motile behavior in mounds. In examining morphogenesis in these strains, we noted that AX-2 mounds tended to culminate directly to a fruiting body, whereas KAX-3 mounds first formed a migratory slug. By altering buffering conditions we could interchange these behaviors and then found that mound-cell motions also changed accordingly. This demonstrates a correlation between mound-cell motion and subsequent development, but it is not obligatory. Chimeric mounds composed of only 10% KAX-3 cells and 90% AX-2 cells exhibited rotational motion, suggesting that a diffusible molecule induces rotation, but many of these mounds still culminated directly, demonstrating that rotational motion does not always lead to slug migration. Our observations provide a detailed analysis of cell motion for two distinct modes of mound and slug formation in Dictyostelium.

A GLRA1 null mutation in recessive hyperekplexia challenges the functional role of glycine receptors.

Dominant missense mutations in the human glycine receptor (GlyR) alpha 1 subunit gene (GLRA1) give rise to hereditary hyperekplexia. These mutations impair agonist affinities and change conductance states of expressed mutant channels, resulting in a partial loss of function. In a recessive case of hyperekplexia, we found a deletion of exons 1-6 of the GLRA1 gene. Born to consanguineous parents, the affected child is homozygous for this GLRA1(null) allele consistent with a complete loss of gene function. The child displayed exaggerated startle responses and pronounced head-retraction jerks reflecting a disinhibition of vestigial brain-stem reflexes. In contrast, proprio- and exteroceptive inhibition of muscle activity previously correlated to glycinergic mechanisms were not affected. This case demonstrates that, in contrast to the lethal effect of a null allele in the recessive mouse mutant oscillator (Glra1 spd-ot), the loss of the GlyR alpha 1 subunit is effectively compensated in man.

An unconventional myosin heavy chain gene from Drosophila melanogaster.

As part of a study of cytoskeletal proteins involved in Drosophila embryonic development, we have undertaken the molecular analysis of a 140-kD ATP-sensitive actin-binding protein (Miller, K. G., C. M. Field, and B. M. Alberts. 1989. J. Cell Biol. 109:2963-2975). Analysis of cDNA clones encoding this protein revealed that it represents a new class of unconventional myosin heavy chains. The amino-terminal two thirds of the protein comprises a head domain that is 29-33% identical (60-65% similar) to other myosin heads, and contains ATP-binding, actin-binding and calmodulin/myosin light chain-binding motifs. The carboxy-terminal tail has no significant similarity to other known myosin tails, but does contain a approximately 100-amino acid region that is predicted to form an alpha-helical coiled-coil. Since the unique gene that encodes this protein maps to the polytene map position 95F, we have named the new gene Drosophila 95F myosin heavy chain (95F MHC). The expression profile of the 95F MHC gene is complex. Examination of multiple cDNAs reveals that transcripts are alternatively spliced and encode at least three protein isoforms; in addition, a fourth isoform is detected on Western blots. Developmental Northern and Western blots show that transcripts and protein are present throughout the life cycle, with peak expression occurring during mid-embryogenesis and adulthood. Immunolocalization in early embryos demonstrates that the protein is primarily located in a punctate pattern throughout the peripheral cytoplasm. Most cells maintain a low level of protein expression throughout embryogenesis, but specific tissues appear to contain more protein. We speculate that the 95F MHC protein isoforms are involved in multiple dynamic processes during Drosophila development.

Mutations affecting the stability of the fushi tarazu protein of Drosophila.

We present a molecular analysis of four dominant alleles of the pair-rule gene ftz. Three of these, the ftzUal alleles, cause anti-ftz segmentation defects and homeotic transformations of the first abdominal segment to the third. These alleles are shown to be missense changes affecting two nearby proline codons. Embryos homozygous for these mutations accumulate higher levels of ftz protein than wild type and show strong persistence of ftz protein, but not RNA. These effects appear to result from stabilization of the ftz protein, since ftz stripes decay much more slowly in mutant embryos than in wild type after injection of the protein synthesis inhibitor cycloheximide. We trace the origin of segmentation defects in ftzUal embryos to repression of the pair-rule gene even-skipped by excess ftz protein during stripe sharpening. Homeotic transformations are shown to be correlated with ectopic expression of the abd-A gene of the bithorax complex. A 12-amino-acid sequence containing the proline residues altered in the ftzUal mutants appears to be conserved in the proteins encoded by other segmentation genes and the vertebrate oncogene myc and may target these proteins for rapid degradation. The fourth allele examined, T(2;3)ftzRpl(Rpl), also causes homeotic transformations and is a translocation broken within the ftz-coding region. Both ftz transcript and protein stripes are persistent in Rpl embryos, suggesting that the Rpl RNA is stabilized relative to wild type.

Characterization of anguibactin, a novel siderophore from Vibrio anguillarum 775(pJM1).

Anguibactin, a siderophore produced by cells of Vibrio anguillarum 775 harboring the pJM1 plasmid, has now been isolated from the supernatants of iron-deficient cultures. This iron-reactive material was purified by adsorption onto an XAD-7 resin and subsequent gel filtration on a Sephadex LH-20 column. The resulting neutral compound produced an ion at m/z 348 in mass spectrometry and contained one sulfur, four oxygen, and four nitrogen atoms as determined by elemental analysis. Its strong UV absorbance and blue fluorescence were suggestive of a phenolic moiety. In colorimetric reactions anguibactin behaved like a catechol. The catechol assignment was supported by the appearance of a new absorption band at 510 nm in the ferric complex and by the appearance of peaks at 1,367, 1,447, 1,469, and 1,538 cm-1 in the resonance Raman spectrum. In addition, the infrared spectrum gave evidence of a secondary amide function, but no free carboxylic acid or hydroxamic acid groups were observed. A third iron-ligating group was suggested by the liberation of three protons during iron binding; mass spectrometry of the resulting material yielded a molecular ion characteristic of a 1:1 complex of ferric anguibactin. The purified anguibactin exhibited specific growth-promoting activity under iron-limiting conditions for a siderophore-deficient mutant of V. anguillarum 775(pJM1). A novel structure for anguibactin was indicated by the failure of a large number of known siderophores and synthetic chelators to yield a similar type of specific cross-feeding in the V. anguillarum bioassay.