Post on 04-Apr-2018
DEVELOPMENTAL GENETICS, BIRTH DEFECT & PRENATAL DIAGNOSIS
M. Mansyur RomiDepartemen Anatomi, FK UGM
Tim Genetika Klinik RSUP DR.SARDJITO YOGYAKARTA
The Genetic Basis of Development
How do cells with the same genes grow up to be so different?
Three Procceses of Development The transformation from a zygote into an
organism Results from three interrelated processes:
cell division, cell differentiation morphogenesis
Figure 21.3a, b(a) Fertilized eggs of a frog
(b) Tadpole hatching from egg
Through a succession of mitotic cell divisions The zygote gives rise to a large number of cells
In cell differentiation Cells become specialized in structure and function
Morphogenesis encompasses the processes That give shape to the organism and its various parts
Differential gene expression Nearly all the cells of an organism have genomic
equivalence, that is, they have the same genes
Differences between cells in a multicellular organism differences in gene expression not from differences in the cells’ genomes
yields a variety of cell types each expressing a different combination of genes multicellular eukaryotes
cells become specialized as a zygote develops into a mature organism
Cell Differentiation
Different types of cells Make different proteins because different combinations of
genes are active in each type
Muscle cell Pancreas cells Blood cells
Cell Diferentiation
may retain all of their genetic potential Most retain a complete set of genes May be totipotent
Differentiated cells
The Stem Cells of Animals A stem cell Is a relatively unspecialized cell Can reproduce itself indefinitely Can differentiate into specialized cells of one or
more types, given appropriate conditions
Totipotentcells
Liver cells Nerve cells
Early human embryoat blastocyst stage(mammalian equiva-lent of blastula) From bone marrow
in this example
PluripotentcellsCultured
stem cells
Differentcultureconditions
Differenttypes ofdifferentiatedcells
Blood cells
Embryonic stem cells
Adult stem cellsEmbryonic and Adult Stem Cells Stem cells can be isolated From
early embryos at the blastocyst stage
Adult stem cells pluripoten
t, able to give rise to multiple but not all cell types
Complex assemblies of proteins control eukaryotic transcription
A variety of regulatory proteins interact with DNA and with each other
To turn the transcription of eukaryotic genes on or off
Transcriptional Regulation of Gene Expression During Development
Assist in initiating eukaryotic transcriptionEnhancers Promoter
Gene
DNA Activatorproteins
Otherproteins
Transcriptionfactors
RNA polymerase
Bendingof DNA
Transcription
Transcription Factors
Cytoplasmic Determinants and Cell-Cell Signals in Cell Differentiation
Cytoplasmic determinants in the cytoplasm of the unfertilized egg Regulate the expression of genes in the zygote that affect
the developmental fate of embryonic cells
Sperm
Molecules of another cyto-plasmic deter-minant
Unfertilized egg cell
Molecules of a a cytoplasmicdeterminant Fertilization
Zygote(fertilized egg)
Mitotic cell division
Two-celledembryo
Nucleus
Sperm
Induction
Signal molecules from embryonic cells cause transcriptional changes in nearby target cells
Early embryo(32 cells)
NUCLEUS Signaltransductionpathway
Signalreceptor
Signalmolecule(inducer)
Induction by nearby cells. The cells at the bottom of the early embryo depicted here are releasing chemicals that signal nearby cells to change their gene expression.
(b)
Pattern Formation
Pattern formation in animals and plants results from similar genetic and cellular mechanisms
Pattern formation Is the development of a spatial organization of tissues and
organs Occurs continually in plants Is mostly limited to embryos and juveniles in animals
Cell Positioning Positional information
Consists of molecular cues that control pattern formation
Tells a cell its location relative to the body’s axes and to other cells
Cascades of gene expression and cell-to-cell signaling direct the development of an animal
Early understanding of the relationship between gene expression and embryonic development
Came from studies of mutants of the fruit fly Drosophila melanogaster
THE GENETIC CONTROL OF EMBRYONIC DEVELOPMENT
Eye
Antenna
LegS
EM
50
Head of a normal fruit fly Head of a developmental mutant
What Are Birth Defects?
Birth defects are defined as abnormalities of structure, function, or body metabolism that are present at birth. These abnormalities lead to mental or physical disabilities or are fatal.
There are more than 4,000 different known birth defects ranging from minor to serious, and although many of them can be treated or cured, they are the leading cause of death in the first year of life.
What Are Birth Defects?
Birth defects are defined as abnormalities of structure, function, or body metabolism that are present at birth. These abnormalities lead to mental or physical disabilities or are fatal.
There are more than 4,000 different known birth defects ranging from minor to serious, and although many of them can be treated or cured, they are the leading cause of death in the first year of life.
Birth Defects Some babies survive the pregnancy but are born with
serious problems called birth defects. 3% of all live-born infants have an major
anomaly Additional anomalies are detected during
postnatal live – about 6% at 2 year-olds, 8% in 5year-olds, other 2% later
Single minor anomalies are present in about 14% of newborns
Birth defects Major anomalies are more common in early embryos
(up to 15%) than they are in newborns (3%). Most severely malformed embryos are spontaneously aborted during first 6 to 8 weeks.
Some birth defects include: Cerebral Palsy Cleft Lift and/or palate Down Syndrome Muscular Dystrophy Sickle Cell Anemia Spina Bifida and more!
Causes of Birth Defects Some causes are environmental because it is during
the first few weeks that a baby develops all the bodily systems needed for survival The mother’s diet Any diseases or infections the mother has Harmful substances Some medicines Exposure to hazards (such as chemicals, X-rays,
etc.) Some causes are hereditary
Sometimes a child inherits a defective gene that is dominant such as Huntington's
Some conditions affect only one sex and usually it’s the males Hemophilia Color blindness and more
More Causes of Birth defects
Errors in chromosomes Such as when a baby has too many
or too few chromosomes or has broken or rearranged chromosomes
This usually leads to Down Syndrome
Problems in Prenatal Development
Sometimes a pregnancy begins, but a baby doesn’t develop normally If the baby dies before the 20th
week it is called a miscarriage If the baby dies after that time, it
is called a stillbirth. 15-20% of recognized pregnancies
end in miscarriage 2% ends in stillbirth
Pertanyaan klasik: ? Kelamin janin ? ? Janin normal ?
Peralatan lama: Variabel ukuran uterus Kenaikan BB ibu Auskultasi jantung janin
Peralatan abad XX 1950an: analisis sel janin dr cairan amnion
utk keberadaan sex chromatin 1966: kultur sel dr cairan amnion 1972: USG utk diagnosis anencephaly Saat ini USG mampu menilai hampir
seluruh anatomi janin
Penafsiran diagnosis pranatal bergantung:
Sampel yg dapat diperoleh Teknik yg dapat dipakai Informasi yg dapat diolah
Ragam sampel: Serum maternal, untuk:
Penanda (marker) cerminan kesehatan janin Protein yg berasal dr janin
Cairan amnion, untuk: Bahan yg dpt dianalisis (analytes) Sel yg berasal dr janin
Villus chorion, untuk: sel trofoblast Sel darah janin: eritrosit & lekosit
Teknik yg dipakai
Sampling darah maternal Amniocentesis Chorionic villous sampling (CVS) Cordocentesis Ultrasonography (USG) Embryo biopsy
Penapisan (screening) serum maternal Alfa fetoprotein (AFP)
Produksi dlm hepar janin, puncak: mgg 10-13 Dlm darah maternal lewat placenta atau difusi
menembus membran Konsentrasi puncak : mgg 24-32
Some causes of increased maternal serum AFP concentration Undersestimated gestational age Threatened abortion Multiple pregnancy Fetal abnormality: anencephaly, open neural tube
defect, anterior abdominal wall defect, Turner’s syndrome, bowel atresias, skin defects
Placental hemangioma
Decreased matenal serum AFP concentration: Trisomy 21, 18
Triple screen: AFP Human chorionic gonadotropin (HCG)
Disekresi embryo baru implantasi Unconjugated estrogen (UE)
Amniocentesis Cairan amnion volume> dg usia: 15-350
ml berisi: urin janin + bahan maternal normal steril dan tahan infeksi perlakuan umumnya pd trimester dua dg
risiko kematian janin 0,5 % perlakuan dini: mgg 12-15 dg risiko 2-11%
amniocentesis
Indikasi Analisis kromosom dari sel amnion yang
dikultur: trisomi 21 dsb Estimasi konsentrasi AFP dan aktifitas
acetylcholin esterase (Ache): neural tube defects
Analisis biokimiawi cairan amnion dan sel kultur: inborn error of metabolism
CVS Sel trofoblas: cermin status genetik janin cepat berproliferasi, tak perlu kultur sumber utk:
karyotype pemeriksaan DNA pengukuran aktifitas enzim yg diekspresi
derivat fibroblast perlakuan mgg 9-11 dg risiko kematian
janin 2-13%
Chorionic Villus Sampling (CVS)
Indication for CVS Diagnosis of chromosomal disorders Increasing number of inborn error of
metabolism DNA analysis
Cordocentesis Dilakukan bila cara lain utk mdpt sel janin
takcukup atau serum fetal sangat perlu dikaji
sel janin utk: karyotyping bila dg cara lain tampak mosaicism
darah janin utk: mengukur protein serum hanya di pusat sangat khusus, risiko
kematian janin 0-3%
USG
Informasi anatomis dan fungsional janin mengungkap struktur: kepala, thorax,
abdomen, skeleton dan pertumbuhan janin real time usg: struktur & aktifitas jantung modern usg utk rincian anatomi janin:
ukuran & posisi ruang jantung, ventriculus cerebri, aorta & a.pulmonalis
MENGAPA PERLU MEMPELAJARI GENETIKA? Pergeseran pola : penyakit ‘lingkungan
‘(malnutrisi & infeksi) menurun, penyakit degeneratif & genetik meningkat
Terungkapnya peran faktor genetik sebagai penyebab penyakit pada manusia
Turunnya angka kematian bayi: Indonesia: 142%o(71)67%o(91),DIY:62%o(‘80)26%o(‘92)15,5%o(‘00)
Meluasnya konsep keluarga kecil
Genetically determined diseases Chromosomal disorders Single gene disorders Polygenic or multifactorial diseases Somatic cell genetic disorders
Mitochondrial genetic disorders
RAGAM PENYAKIT GENETIKKELAINAN KROMOSOMAL Pada umumnya jarang Pola pewarisan tidak jelas Biasanya resiko kerabat rendah
KELAINAN GEN TUNGGAL/MONOGENIK Jumlah ragamnya banyak, masing-masing kasusnya
sedikit Pola pewarisan jelas, ikuti hukum Mendel Resiko kerabat tinggi
PENYAKIT POLIGENIK/MULTIFAKTORIAL Banyak dijumpai Pola pewarisan tidak jelas Resiko kerabat rendah-sedang
KELAINAN MUTASI SEL SOMATIK Mungkin ada gambaran “mosaik” Menyebabkan neoplasia/keganasan
KELAINAN GEN MITOKHONDRIA Pola pewarisan”maternal”atau sporadic
Birth defects Major anomalies are more common in early embryos
(up to 15%) than they are in newborns (3%). Most severely malformed embryos are spontaneously aborted during first 6 to 8 weeks.
Some birth defects include: Cerebral Palsy Cleft Lift and/or palate Down Syndrome Muscular Dystrophy Sickle Cell Anemia Spina Bifida and more!