@misc{oai:ir.soken.ac.jp:00004086,
 author = {片岡, 太郎 and カタオカ, タロウ and KATAOKA, Taro},
 month = {2016-02-26, 2016-02-17},
 note = {Bones have crucial roles in supporting body as one of the locomotor
apparatuses, maintaining mineral homeostasis and protecting vital organs.
Bone tissues are classified into two types by visual appearance and location,
“cancellous (trabecular) bone” and “cortical bone”. Cancellous bone, also
known as sponge bone, is found in vertebral body and both ends of long bone
like tibia and femur. It has larger surface area but shows weaker strength
than cortical bone. It provides structural strength to bone tissue. Cortical
bone forms cortex of most bones. It is stronger and stiffer than cancellous
bone. The outer shell surrounding the cancellous bone at the end of the joints
is also made up of cortical bone.
Bones in adulthood are continuously renewed by old bone resorption by
osteoclasts and new bone formation by osteoblasts. This process is called
“bone remodeling”. Bone remodeling is important for bone homeostasis, and is
essential for maintenance of healthy bones. Disruption of ideal balance in
bone remodeling causes abnormal bone mass such as osteoporosis and
osteopetrosis. A series of longitudinal studies of human populations have
showed that bone mineral density (BMD) is correlated with physical strength
of bone, and a most important risk factor for bone fracture.
However, human studies also indicated that BMD at any time points is well
correlated with peak (highest) bone mass in the early growth phase of bone.
Furthermore, these studies have also revealed that more than half of
variation in the early growth phase of bone, which occurs over a short time
period during puberty, is determined predominantly by genetic factors.
Recent advance in X-ray micro-computed tomography (micro-CT) has
enabled to analyze three-dimensional (3D) structure of the cancellous bones
without tissue destruction. Such studies have indicated that the risk of bone
fracture in human elders increases as BMD decreases, but the biomechanical
competence (physical strength) of bone and risk factor of bone fracture are
dependent not only on BMD as the absolute amount of bone mass, but also on
the 3D microstructure of cancellous bone. This fact suggests that we need to
pay more attention to bone microstructure for identifying genetic risk factors
for bone fracture. Recent studies also showed that there is a very good
correlation between the bone microstructural measure obtained from the
X-ray micro-CT and that obtained from conventional histological 2D sections.
In particular, excellent correlation was found between bone volume fraction
(BV/TV), which is the measure of cancellous bone volume per total volume
surrounded by cortical bone, and the data of the histological 2D sections.
Subsequent studies of microstructure of mouse cancellous bone by X-ray
micro-CT have also showed that cancellous bone loss is observed even in the
early growth phase of bone, and occurs continuously until the later adulthood
stage, consistent with facts that cancellous bone is highly sensitive to change
of bone metabolism, and is easily fractured in human elders.
Forward genetics approaches to explore polygenic factors responsible for bone
homeostasis can be efficiently pursued in animal models. Usage of the animal
models enables to control genome heterogeneity and environmental factors,
and improves the power to identify heritable regulation of bone homeostasis.
Variations in genome sequences and bone phenotypes among different inbred
strains of mice are amenable to genetic analyses of polygenic complex traits of
bone phenotypes via the quantitative trait loci (QTL) analysis. In fact, several
studies with inbred mouse strains have revealed QTLs that affect
microstructure of mouse cancellous bone. However, none of causative genes
for the QTLs has been identified so far.
In this study, I focused on genetic factors responsible for variation in
microstructure of mouse cancellous bone at the earlier growth phase of 6 to 10
weeks of age, because the early growth phase is critical for bone density and
microstructure at any time in the later adulthood stage. The genes that
regulate bone formation during embryonic development have been intensively
studied by reverse genetics approaches with knockout mouse strains, and the
genes involved in bone homeostasis at the later adulthood stage have been
extensively studied by genome wide association study for human populations.
By contrast, there is only limited information for genes acting for forming
bone microstructure at the earlier and growing phase of bone. This is another
reason that I focused on the early growth phase of mouse bone. For genetic
analyses in this study, I used two strains, a laboratory inbred strain C57BL/6J
(hereafter abbreviated B6) and Japanese wild mouse (Mus musculus
molossinus)-derived MSM/Ms.
These two strains are genetically very distant one another, and more than ten
million SNPs have been identified between these two strains, and the SNP
data are now fully available. As a consequence of its genome divergence from
B6 and other laboratory strains, MSM/Ms appeared to have unique complex
traits that are never observed in standard laboratory strains. Another great
advantage to use the B6 and MSM/Ms strains is that a full set of consomic
strains, in which every B6 chromosome is replaced by counterpart of
MSM/Ms, is now established and available for exploring QTLs.
At the beginning of this study, the X-ray micro-CT phenotyping of
microstructure of cancellous bone of tibia at 10 weeks of age showed that
MSM/Ms has far smaller value of bone volume fraction (BV/TV) than that of
B6. This finding prompted me to pursue systematic phenotype screening of
the same trait for the full set of B6-MSM/Ms consomic strains. As a result, I
found that among all consomic strains B6-Chr15MSM carrying MSM/Ms-derive
chromosome 15 (Chr15) shows the smallest cancellous bone volume fraction,
indicating that mouse Chr15 harbors QTLs affecting bone microstructure,
which is likely relevant to bone physical strength. Next, in order to further
dissect genetic factors into sub-regions of Chr15, I generated nested
sub-consomic strains that harbor sub-divided fragments of MSM/Ms Chr15.
Bone phenotyping of these strains revealed that at least four chromosomal
blocks of Chr15 genetically control the trait of cancellous bone microstructure.
I named these blocks, Block 1 to 4, each of which contains at least one QTL
affecting microstructure of cancellous bone. None of these four QTLs has been
reported by other groups’ previous studies.
It is of interest to note that the MSM/Ms alleles at the QTLs in the Block 2, 3
and 4 decrease the bone volume fraction (BV/TV) relative to B6 as were
expected, but the MSM/Ms allele at the QTL in Block 1 rather increases the
BV/TV value relative to B6. Thus, the analysis with the sub-consomic strains
revealed marked complexity of genetic architecture to control cancellous bone
microstructure in mouse, and demonstrated that the analysis with consomic
and sub-consomic strains has strong power to detect each of numerous QTLs,
even if its phenotypic effect is modest.
Finally, I paid special attention to one short sub-block, named Sub-block 1-1,
included in Block 1, the borders of which are defined by difference in the
MSM/Ms-derived fragments of two sub-consomic strains. I intensively
explored candidates of the causative gene for the QTL in Sub-block 1-1,
because no known gene to be involved in bone regulation and homeostasis is
assigned to this interval. I identified eight genes as candidates. In particular,
four of them, Ankrd33b, Ropn1l, March6 and Fam173b, are good candidates
from the aspects of expression pattern difference and amino acid change
between B6 and MSM/Ms. Thus, this study provides indispensable clues for
understanding genetic architecture underlying bone regulation and
homeostasis of mouse, and for searching genetic factors responsible for
osteoporosis in human., application/pdf, 総研大甲第1606号},
 title = {Exploration of genetic factors controlling cancellous bone microstructure of mouse},
 year = {}
}