wingless

EVOLUTIONARY HOMOLOGS

page 1

Wnt receptors
Role of low-density lipoprotein receptor (LDLR)-related protein (LRP) family genes in Wnt signaling
Heparan sulfate proteoglycans and Wnt signaling
Frzb(s), proteins that interfere with Wnt signalling by binding to Wnt receptors
Other secreted antagonists of Wnt signaling
R-Spondin2 is a secreted activator of Wnt/ß-Catenin signaling and is required for Xenopus myogenesis
CCN family proteins: Extracellular-matrix constituents that modulate WNT signaling
Wnt signaling is modified by Carboxypeptidase Z
Transcriptional regulation of Wnts
Lipid modification of Wnts
Wntless transports Wnt from the Golgi network to the cell surface for release

page 2

Canonical and non-canonical Wnt signaling pathways

page 3

Wnts in worms: asymmetric cell division and cell fate determination
Opposing Wnt pathways orient cell polarity during organogenesis
The C. elegans ROR receptor tyrosine kinase, CAM-1, non-autonomously inhibits the Wnt pathway
Wnt-Ror signaling to SIA and SIB neurons directs anterior axon guidance and nerve ring placement in C. elegans
Wnt gradient formation in C. elegans requires retromer function in Wnt-producing cells
Two Wnts instruct topographic synaptic innervation in C. elegans
Wnt signaling positions neuromuscular connectivity by inhibiting synapse formation in C. elegans
Reciprocal signaling by Wnt and Notch specifies a muscle precursor in the C. elegans embryo
C. elegans AP-2 and Retromer control Wnt signaling by regulating MIG-14/Wntless
Neuroblast migration along the anteroposterior axis of C. elegans is controlled by opposing gradients of Wnts

page 4

Wnts and insect segmentation
Wingless and insect wing patterns
Wingless and insect leg development
Wingless and parasegmental organization in invertebrates
Wnts in other invertebrate species
Wnt genes in amphioxus and the evolution of somitogenesis

page 5

Wnts function in zebrafish
Wnt pathway activation as a consequence of cortical rotation in Xenopus
Wnts and the Xenopus Organizer
Wnts, A/P patterning, and tail formation
Wnt-5A/Ror2 regulate expression of XPAPC through an alternative noncanonical signaling pathway

page 6

Effects of Wnt mutation
Wnts and axis formation
Wnts and posterior development
Wnts and cell migration
Wnt regulation during gastrulation
Wnts and left-right asymmetry

page 7

Wnts, mesoderm and somitogenesis
Wnts and heart development
Wnts and kidney, liver and pancreas development
Wnts and lung development
Wnts and tissue polarity
Wnts and pituitary gland

page 8

Wnts and neural patterning and differentiation
Mesodermal Wnt signaling organizes the neural plate via Meis3
Wnt signaling determines ventral spinal cord cell fates in a time-dependent manner
Wnts and the patterning of the forebrain
Wnt targets in the telencephalon
Wnt signaling and its downstream target N-myc regulate basal progenitors in the developing neocortex
Wnts and the patterning of the midbrain
Wnts and axon guidance
Wnts and synaptogenesis

page 9

Wnts and epidermis
Wnts and hair development
Wnts and adipogenesis
Wnts and mammary gland morphogenesis
WNTs and neural crest
Wnts and eye development
Wnts and ear development
Wnts and tooth development

page 10

Wnts and limb patterning
Wnts and urogenital development
Wnts and gonadal development
Wnts and external genitalia
Wnts and uterine development
Wnts and placentation defects
Wnt signaling and stem cells
Wnts and organ development
Oncogenic targets of Wnts
A Wnt/ß-Catenin --> Pitx2 pathway controls the turnover of Pitx2 and other unstable mRNAs

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