An open-source dual-beam spectrophotometer for citizen-science-based water quality monitoring.

Efforts to understand and mediate threats to water supplies rely on collection of reliable data at large scale, a goal which is often limited by availability of tools that are both affordable and reliable. We present here a low-cost, easy-to-use, do-it-yourself (DIY) spectrometer for measurement of a variety of relevant solute concentrations when coupled with inexpensive commercially-available reagents. Comparison of its performance with commercial options demonstrates the potential value of this device as transparent, versatile, and accurate-enough alternative for widespread application.

Evaluation of in vivo bioactivities of recombinant hypo- (FSH21/18) and fully- (FSH24) glycosylated human FSH glycoforms in Fshb null mice.

The hormone - specific FSHß subunit of the human FSH heterodimer consists of N-linked glycans at Asn7 and Asn24 residues that are co-translationally attached early during subunit biosynthesis. Differences in the number of N-glycans (none, one or two) on the human FSHß subunit contribute to macroheterogeneity in the FSH heterodimer. The resulting FSH glycoforms are termed hypo-glycosylated (FSH21/18, missing either an Asn24 or Asn7 N-glycan chain on the ß - subunit, respectively) or fully glycosylated (FSH24, possessing of both Asn7 and Asn24 N-linked glycans on the ß - subunit) FSH. The recombinant versions of human FSH glycoforms (FSH21/18 and FSH24) have been purified and biochemically characterized. In vitro functional studies have indicated that FSH21/18 exhibits faster FSH- receptor binding kinetics and is much more active than FSH24 in every assay tested to date. However, the in vivo bioactivity of the hypo-glycosylated FSH glycoform has never been tested. Here, we evaluated the in vivo bioactivities of FSH glycoforms in Fshb null mice using a pharmacological rescue approach. In Fshb null female mice, both hypo- and fully-glycosylated FSH elicited an ovarian weight gain response by 48 h and induced ovarian genes in a dose- and time-dependent manner. Quantification by real time qPCR assays indicated that hypo-glycosylated FSH21/18 was bioactive in vivo and induced FSH-responsive ovarian genes similar to fully-glycosylated FSH24. Western blot analyses followed by densitometry of key signaling components downstream of the FSH-receptor confirmed that the hypo-glycosylated FSH21/18 elicited a response similar to that by fully-glycosylated FSH24 in ovaries of Fshb null mice. When injected into Fshb null males, hypo-glycosylated FSH21/18 was more active than the fully-glycosylated FSH24 in inducing FSH-responsive genes and Sertoli cell proliferation. Thus, our data establish that recombinant hypo-glycosylated human FSH21/18 glycoform elicits bioactivity in vivo similar to the fully-glycosylated FSH. Our studies may have clinical implications particularly in formulating FSH-based ovarian follicle induction protocols using a combination of different human FSH glycoforms.