Planar induction of anteroposterior pattern in the developing central nervous system of Xenopus laevis.

It has long been thought that anteroposterior (A-P) pattern in the vertebrate central nervous system is induced in the embryo's dorsal ectoderm exclusively by signals passing vertically from underlying, patterned dorsal mesoderm. Explants from early gastrulae of the frog Xenopus laevis were prepared in which vertical contact between dorsal ectoderm and mesoderm was prevented but planar contact was maintained. In these, four position-specific neural markers (engrailed-2, Krox-20, XlHbox 1, and XlHbox 6) were expressed in the ectoderm in the same A-P order as in the embryo. Thus, planar signals alone, following a path available in the normal embryo, can induce A-P neural pattern.

Activity of the sex-determining gene tra-2 is modulated to allow spermatogenesis in the C. elegans hermaphrodite.

In the nematode C. elegans, there are two sexes, the self-fertilizing hermaphrodite (XX) and the male (XO). The hermaphrodite is essentially a female that makes sperm for a brief period before oogenesis. Sex determination in C. elegans is controlled by a pathway of autosomal regulatory genes, the state of which is determined by the X:A ratio. One of these genes, tra-2, is required for hermaphrodite development, but not for male development, because null mutations in tra-2 masculinize XX animals but have no effect on XO males. Dominant, gain-of-function tra-2 mutations have now been isolated that completely feminize the germline of XX animals so that they make only oocytes and no sperm and, thus, are female. Most of the tra-2(dom) mutations do not correspondingly feminize XO animals, so they do not appear to interfere with control by her-1, a gene thought to negatively regulate tra-2 in XO animals. Thus, these mutations appear to cause gain of tra-2 function in the XX animal only. Dosage studies indicate that 5 of 7 tra-2(dom) alleles are hypomorphic, so they do not simply elevate XX tra-2 activity overall. These properties suggest that in the wild type, tra-2 activity is under two types of control: (1) in males, it is inactivated by her-1 to allow male development to occur, and (2) in hermaphrodites, tra-2 is active but transiently inactivated by another, unknown, regulator to allow hermaphrodite spermatogenesis; this mode of regulation is hindered by the tra-2(dom) mutations, thereby resulting in XX females.

Natural variation and copulatory plug formation in Caenorhabditis elegans.

Most of the available natural isolates of the nematode Caenorhabditis elegans have been examined and compared with the standard laboratory wild type (Bristol N2). Molecular markers, in particular transposon restriction fragment length polymorphisms, were used to assign these isolates to 22 different races, for which brood size and spontaneous male frequency were determined. Several distinctive traits were observed in some of these races. One example is mab-23, in a race from Vancouver, which leads to severe distortion of male genitalia and prevents male mating. Another is gro-1, segregating in a Californian race, which is associated with slow growth, heat resistance and longevity. Many races differ from N2 in carrying a dominant allele at the plg-1 locus, causing copulatory plug formation by males. Properties and possible advantages of the plugging trait have been investigated. The dominant plg-1 allele does not lead to increased male mating efficiency, but males from a Stanford race (CB4855), in which the plugging trait was first observed, are much more virile than N2 males. Crosses between N2 and CB4855 indicate that the higher virility is due to multiple factors. Size differences between N2 and CB4855 are associated with factors mapping to LGV and LGX.

Induction of anteroposterior neural pattern in Xenopus: evidence for a quantitative mechanism.

The developing vertebrate nervous system arises from ectoderm in response to inductive signals from the dorsal mesoderm, or Spemann organizer. It displays pronounced anteroposterior (AP) pattern, but the mechanism that generates this pattern is poorly understood. We demonstrate that the inducing ability of dorsal mesoderm is regionalized along the AP axis at the early gastrula stage, using the homeodomain-encoding genes Xanf-2 and en-2 as markers of anterior and mid-neural pattern, respectively. In addition, we show that changing the size ratio of posterior dorsal mesoderm to responding ectoderm affects the type of AP pattern induced. A low ratio leads to induction of anterior neural pattern, while a high ratio leads to expression of only mid-neural pattern. These and other results indicate that a quantitative mechanism specifies AP neural pattern.

Planar and vertical induction of anteroposterior pattern during the development of the amphibian central nervous system.

In amphibians and other vertebrates, neural development is induced in the ectoderm by signals coming from the dorsal mesoderm during gastrulation. Classical embryological results indicated that these signals follow a "vertical" path, from the involuted dorsal mesoderm to the overlying ectoderm. Recent work with the frog Xenopus laevis, however, has revealed the existence of "planar" neural-inducing signals, which pass within the continuous sheet or plane of tissue formed by the dorsal mesoderm and presumptive neurectoderm. Much of this work has made use of Keller explants, in which dorsal mesoderm and ectoderm are cultured in a planar configuration with contact along only a single edge, and vertical contact is prevented. Planar signals can induce the full anteroposterior (A-P) extent of neural pattern, as evidenced in Keller explants by the expression of genes that mark specific positions along the A-P axis. In this review, classical and modern molecular work on vertical and planar induction will be discussed. This will be followed by a discussion of various models for vertical induction and planar induction. It has been proposed that the A-P pattern in the nervous system is derived from a parallel pattern of inducers in the dorsal mesoderm which is "imprinted" vertically onto the overlying ectoderm. Since it is now known that planar signals can also induce A-P neural pattern, this kind of model must be reassessed. The study of planar induction of A-P pattern in Xenopus embryos provides a simple, manipulable, two-dimensional system in which to investigate pattern formation.

Induction of anteroposterior neural pattern in Xenopus by planar signals.

Neural pattern in vertebrates has been thought to be induced in dorsal ectoderm by 'vertical' signals from underlying, patterned dorsal mesoderm. In the frog Xenopus laevis, it has recently been found that general neural differentiation and some pattern can be induced by 'planar' signals, i.e. those passing through the single plane formed by dorsal mesoderm and ectoderm, without the need for vertical interactions. Results in this paper, using the frog Xenopus laevis, indicate that four position-specific neural markers (the homeobox genes engrailed-2(en-2), XlHbox1 and XlHbox6 and the zinc-finger gene Krox-20) are expressed in planar explants of dorsal mesoderm and ectoderm ('Keller explants'), in the same anteroposterior order as that in intact embryos. These genes are expressed regardless of convergent extension of the neurectoderm, and in the absence of head mesoderm. In addition, en-2 and XlHbox1 are not expressed in ectoderm when mesoderm is absent, but they and XlHbox6 are expressed in naïve, ventral ectoderm which has had only planar contact with dorsal mesoderm. en-2 expression can be induced ectopically, in ectoderm far anterior to the region normally fated to express it, suggesting that a prepattern is not required to determine where it is expressed. Finally, the mesoderm in planar explants expresses en-2 and XlHbox1 in an appropriate regional manner, indicating that A-P pattern in the mesoderm does not require vertical contact with ectoderm. Overall, these results indicate that anteroposterior neural pattern can be induced in ectoderm soley by planar signals from the mesoderm. Models for the induction of anteroposterior neural pattern by planar and vertical signals are discussed.

A sex-determining gene, fem-1, required for both male and hermaphrodite development in Caenorhabditis elegans.

Sex in the nematode Caenorhabditis elegans is normally determined by the X chromosome to autosome (X:A) ratio, with XX hermaphrodites and XO males. Previous work has shown that a set of at least four autosomal genes (her-1, tra-2, tra-3, and tra-1) is signaled by the X:A ratio and appears to act in a regulatory pathway to determine sex. Twenty-one new recessive alleles of the gene fem-1(IV) (formerly isx-1) have been isolated. Seven of these may be null alleles; one of these is an amber mutation. The other 14 alleles are temperature sensitive. The putative null mutations cause both XO and XX animals to develop as females when the mother as well as the zygote is fem-1(-). Therefore, fem-1(+) is required (a) for the development of the male body and (b) for spermatogenesis in males and hermaphrodites. In addition, fem-1 shows a maternal effect: wild-type fem-1 product partially rescues the development of fem-1(-) progeny. By analyzing double mutants it has been shown that fem-1(+) is part of the sex-determination pathway and has two distinct functions: (1) in the soma it prevents the action of tra-1, thereby allowing male development to occur, and (2) in the germline it is necessary for spermatogenesis in both sexes.

Initiation of anterior head-specific gene expression in uncommitted ectoderm of Xenopus laevis by ammonium chloride.

The role of homeobox-containing genes in the regional specification of the vertebrate embryo has been an area of intense research over the last decade. Whereas it appears that the homeobox genes of the Hox gene family play an important role in the specification of the trunk, the genes and processes involved in the specification of the head are less well understood. We have isolated a new head-specific homeobox gene, XANF-2, that appears to be involved in the regional specification of the anterior head of Xenopus embryos. This gene is initially expressed in the anterior dorsal region of early embryos and later exclusively in the primordium of the anterior pituitary gland. XANF-2 represents the earliest marker for the anterior pituitary lineage. Ammonium chloride is able to induce the expression of XANF-2 in uncommitted ectoderm. These and other data indicate that ammonium chloride is capable of inducing a large portion of the anterior dorsal region of the embryo which includes, but is not limited to, the anterior pituitary gland and cement gland anlagen. This implies that changes in intracellular ionic conditions play an important role in the formation of the anterior head region. In addition to NH4Cl, injection of follistatin RNA can induce transcription of XANF-2, suggesting that these two unrelated compounds can activate a chain of events leading to the formation of the amphibian head. Furthermore, we demonstrate that planar induction in Keller sandwiches can induce XANF-2 expression as well as the expression of the cement gland-specific gene, XCG 13, indicating that planar signaling can account for induction of even the most anterior regions of the embryo.

Cortical rotation of the Xenopus egg: consequences for the anteroposterior pattern of embryonic dorsal development.

We first review cortical-cytoplasmic rotation, a microtubule-mediated process by which the Xenopus egg, like other amphibian eggs, transforms its polarized cylindrical symmetry into bilateral symmetry within the first cell cycle after fertilization. This transformation, the earliest of many steps leading to dorsal development, involves the displacement of the egg's cortex relative to its cytoplasmic core by 30 degrees in an animal-vegetal direction. As rotation is progressively reduced by microtubule-depolymerizing agents, embryos develop with body axes progressively deleted for dorsal structures at the anterior end. With no rotation, ventralized embryos are formed. In an effort to comprehend this progressive effect on embryonic organization, we go on to review subsequent developmental process depending on rotation, and we propose, with evidence, that reduced rotation leads to a reduced number of vegetal dorsalizing cells, which induce during the blastula stage a Spemann organizer region of smaller than normal size. The reduced organizer then promotes a reduced amount of cell rearrangement (morphogenesis) at gastrulation. Reduced morphogenesis seems the proximate cause of the incompleteness of axial pattern, as shown further by the fact that embryos that are normal until the gastrula stage, if exposed to inhibitors of morphogenesis, develop body axes that are progressively less complete in their anterior dorsal organization the earlier their gastrulation had been blocked. We discuss why axial pattern might depend systematically on morphogenesis.