Abnormal social behavior in mice with tyrosinemia type I is associated with an increase of myelin in the cerebral cortex.

Hereditary tyrosinemia type I (HT1) is caused by mutations in the fumarylacetoacetate hydrolase (FAH) gene, the template for the final enzyme in the tyrosine catabolism pathway. If left untreated this deficiency of functional FAH leads to a buildup of toxic metabolites that can cause liver disease, kidney dysfunction and high mortality. The current treatment with the drug NTBC prevents the production of these metabolites and has consequently increased the survival rate in HT1 children. As a result of this increased survival, long term complications of HT1 are now being observed, including slower learning, impaired cognition and altered social behavior. We studied a mouse model of HT1 to gain insight into the effects of HT1 and treatment with NTBC on social behavior in mice. We showed that mice with HT1 display abnormal social behavior in that they spend more time in the absence of another mouse and do not discriminate between a novel mouse and an already familiar mouse. This altered behavior was due to HT1 and not treatment with NTBC. Quantification of cerebral cortex myelin in mice with HT1 showed a two to threefold increase in myelin expression. Our findings suggest that absence of FAH expression in the brain produces an altered brain biochemistry resulting in increased expression of myelin. This increase in myelination could lead to abnormal action potential velocity and altered neuronal connections that provide a mechanism for the altered learning, social behavior and cognitive issues recently seen in HT1.

Tyrosinemia type I and not treatment with NTBC causes slower learning and altered behavior in mice.

Tyrosinemia type I is a recessive inborn error of metabolism caused by mutations in the fumarylacetoacetate hydrolase (FAH) gene, coding for the final enzyme in the metabolism of tyrosine. This renders FAH nonfunctional and without treatment, toxic metabolites accumulate causing liver and kidney damage. Introduction of the drug NTBC in 2002 offered a treatment which inhibits an upstream enzyme, preventing the production of the toxic metabolites. There is now a long-term survival rate of greater than 90 % in children, but there are reports of lower cognitive function and IQ as well as schooling and behavioral problems in these children. We studied a mouse model of tyrosinemia type I to gain insight into the effects of tyrosinemia type I and treatment with NTBC on mouse learning, memory, and behavior. In the Barnes maze, visual and spatial cues can be used by mice to remember the location of a dark escape box. The primary time, distance, and strategy taken by the mice to locate the escape box is a measure of learning and memory. Our findings show that mice with tyrosinemia type I were slower to learn than wild-type mice treated with NTBC and made more mistakes, but were capable of learning and storing long-term memory. After learning the location of the target hole, mice with tyrosinemia type I respond differently to a change in location and were less flexible in learning the new target hole location. Our findings suggest that this slower learning and cognitive difference is caused by tyrosinemia type I and not by the treatment with NTBC.

Association of Aortic Stiffness With Biomarkers of Neuroinflammation, Synaptic Dysfunction, and Neurodegeneration.

OBJECTIVES: To test the hypothesis that increased aortic stiffening is associated with greater CSF evidence of core Alzheimer disease pathology (ß-amyloid [Aß], phosphorylated tau [p-tau]), neurodegeneration (total tau [t-tau]), synaptic dysfunction (neurogranin), neuroaxonal injury (neurofilament light [NFL]), and neuroinflammation (YKL-40, soluble triggering receptor expressed on myeloid cells 2 [sTREM2]), we analyzed pulse wave velocity (PWV) data and CSF data among older adults. METHODS: Participants free of stroke and dementia from the Vanderbilt Memory and Aging Project, an observational community-based study, underwent cardiac magnetic resonance to assess aortic PWV (meters per second) and lumbar puncture to obtain CSF. Linear regressions related aortic PWV to CSF Aß, p-tau, t-tau, neurogranin, NFL, YKL-40, and sTREM2 concentrations after adjustment for age, race/ethnicity, education, apolipoprotein (APOE) ε4 status, Framingham Stroke Risk Profile, and cognitive diagnosis. Models were repeated testing PWV interactions with age, diagnosis, APOE ε4, and hypertension on each biomarker. RESULTS: One hundred forty-six participants were examined (age 72 ± 6 years). Aortic PWV interacted with age on p-tau (ß = 0.31, p = 0.04), t-tau, (ß = 2.67, p = 0.05), neurogranin (ß = 0.94, p = 0.04), and sTREM2 (ß = 20.4, p = 0.05). Among participants >73 years of age, higher aortic PWV related to higher p-tau (ß = 2.4, p = 0.03), t-tau (ß = 19.3, p = 0.05), neurogranin (ß = 8.4, p = 0.01), and YKL-40 concentrations (ß = 7,880, p = 0.005). Aortic PWV had modest interactions with diagnosis on neurogranin (ß = -10.76, p = 0.03) and hypertension status on YKL-40 (ß = 18,020, p < 0.001). CONCLUSIONS: Among our oldest participants, ≥74 years of age, greater aortic stiffening is associated with in vivo biomarker evidence of neuroinflammation, tau phosphorylation, synaptic dysfunction, and neurodegeneration, but not amyloidosis. Central arterial stiffening may lead to cumulative cerebral microcirculatory damage and reduced blood flow delivery to tissue, resulting in neuroinflammation and neurodegeneration in more advanced age.