Regular articles: conditional disruption of hedgehog signaling pathway defines its critical role in hair development and regeneration.

Members of the vertebrate hedgehog family (Sonic, Indian, and Desert) have been shown to be essential for the development of various organ systems, including neural, somite, limb, skeletal, and for male gonad morphogenesis. Sonic hedgehog and its cognate receptor Patched are expressed in the epithelial and/or mesenchymal cell components of the hair follicle. Recent studies have demonstrated an essential role for this pathway in hair development in the skin of Sonic hedgehog null embryos. We have further explored the role of the hedgehog pathway using anti-hedgehog blocking monoclonal antibodies to treat pregnant mice at different stages of gestation and have generated viable offspring that lack body coat hair. Histologic analysis revealed the presence of ectodermal placode and primodium of dermal papilla in these mice, yet the subsequent hair shaft formation was inhibited. In contrast, the vibrissae (whisker) development appears to be unaffected upon anti-hedgehog blocking monoclonal antibody treatment. Strikingly, inhibition of body coat hair morphogenesis also was observed in mice treated postnatally with anti-hedgehog monoclonal antibody during the growing (anagen) phase of the hair cycle. The hairless phenotype was reversible upon suspension of monoclonal antibody treatment. Taken together, our results underscore a direct role of the Sonic hedgehog signaling pathway in embryonic hair follicle development as well as in subsequent hair cycles in young and adult mice. Our system of generating an inducible and reversible hairless phenotype by anti-hedgehog monoclonal antibody treatment will be valuable for studying the regulation and mechanism of hair regeneration.

Retrograde axonal transport of an exogenous enzyme covalently linked to B-IIb fragment of tetanus toxin.

Attempt to replace enzymes in a number of fatal lysosomal storage disease involving the central nervous system have as yet been unsuccessful owing to the impermeability of the blood/brain barrier to macromolecules. In order to treat storage disease due to enzyme deficiencies, we investigated the feasibility of transporting an enzyme into the central nervous system without crossing the blood/brain barrier. Using the B-IIb fragment of tetanus toxin (because it is involved in recognition by the nerve-cell endings), retrograde axonal transport toward the spinal cord and trans-synaptic movement, and glucose oxidase as a marker, we demonstrated that a non-toxic enzyme-vector conjugate was taken up by axon terminals. After injection into the gastrocnemius muscle, the B-IIb-glucose oxidase conjugate was detected, both histologically and electrochemically, distally to a ligature on the sciatic nerve. Thus the B-IIb fragment could serve as a vector for glucose oxidase transport into the central nervous system. It was also verified that the transported enzyme retained its activity. Transport of this 150 kDa molecule by fragment B-IIb of tetanus toxin suggests that other enzymes of a lesser molecular mass may also be transported.

Direct electrochemical determination of glucose oxidase in biological samples.

An electrochemical method for the quantitation of glucose oxidase in murine plasma and tissues has been developed. Instead of oxygen, this method uses benzoquinone as an artificial cosubstrate of glucose oxidase. The quantitative detection of the enzymatically produced hydroquinone by controlled-potential amperometry allows measurement of glucose oxidase concentrations in biological samples. The use of an internal standard corrects for all possible interfering effects. We demonstrated a 10-fold increase in sensitivity, as well as the ability to work in turbid media, in comparison to spectrophotometric methods.