Transcript Document

Introduction
•Gaucher’s Disease – A glycolipid storage disorder characterized by
the accumulation of glucosylceramide in the spleen, liver, lungs,
bone marrow and brain
•The disease is caused by a deficiency of lysosomal acid betaglucosidase, which hydrolyzes glucosylceramide to ceramide and
glucose
•Ceramides are the biological building blocks of Sphingolipids
Introduction cont.
•Sphingolipids – are essential components of the plasma membrane of
eukaryotic cells.
•Sphingolipids differ from phospholipids in being based on a
lipophilic amino alcohol (sphingosine) rather than glycerol.
•Sphingolipids play important roles in signal transduction
Topic
Application of delayed extraction–matrix-assisted laser desorption
ionization time-of-flight mass spectrometry for analysis of
sphingolipids in pericardial fluid, peritoneal fluid and serum from
Gaucher disease patients
Takehisa Fujiwaki , , a, Seiji Yamaguchia, Masaru Tasakaa, Nobuo Sakurab and Tamotsu Taketomic
a
Department of Pediatrics, Shimane Medical University, 89-1 Enya-cho, Izumo 693-8501, Japan
b Department of Pediatrics, Hiroshima University School of Medicine, 1-2-3 Kasumi, Minami-ku,
Hiroshima 734-8551, Japan
c Department of Biochemistry, Research Center on Aging and Adaptation, Shinshu University
School of Medicine, 3-1-1 Asahi-machi, Matsumoto 390-8621, Japan
So, what’s the point????
•The point is……Delayed Extraction – Matrix Assisted
Laser Desorption Ionization - Time Of Flight – Mass
Spectrometry can be used to evaluate patients with
Gaucher’s disease using small amounts of body fluids.
The Basics…..Matrix Assisted Laser Desorption Ionization –
Time Of Flight (MALDI-TOF)
The basics cont……What is the Matrix???????
•The matrix is an organic acid that holds the sample
•Absorbs photon energy and transfers it
•Reduces intermolecular forces and aggregation by serving
as a solvent
The basics cont…Laser Desorption Ionization???
•UV laser is used to generate ions
•The matrix absorbs the energy and transfers the energy to the
sample
•The sample becomes ionized into a gas phase (proton transfer)
The basics cont……Time of Flight????
•Ions enter the mass spectrometer or time-of flight (TOF)
•They are accelerated by high voltage and separated based on the
time it takes them to travel to the detector
•All ions gain same kinetic energy
•A spectrum of ion intensity as a function of travel time is recorded
•The ion’s passage through the drift tube can be described as:
qE = 1/2 m v2 = 1/2 m (l/t)
q= ion charge
v= velocity through drift tube
l= length of tube
t= time of flight through tube
m= ion mass
E= electric field voltage
•Time of flight can be converted to molecular mass:
t ~ (m/q)1/2
Methods
•Sphingolipid fractions from body fluids and serum were collected
•Each sample was mixed with a matrix composed of 2,5
dihydroxybenzoic acid (DHB).
•Advantages of DHB:
•ions undergo little metastable decay
•insensitive to contaminations
•produces minimal interference in the low molecular weight
range
•Samples were loaded into a Voyager DE-RP (2.0 m flight length,
reflector mode) and mass spectra of the samples was obtained in the
positive ion mode with an N2 laser (337nm) and a scan average of
256. Two point external calibration was performed each time.
Delayed Extraction?
•Basically – it groups ions and provides better
resolution
•A time delay between ionization of the sample and extraction
from the ion source
•Allows ions with identical mass/charge values to arrive at the
detector at the same time
External Calibration?
•Internal and external calibration
•External involves acquisition from two samples
•1st sample – two standards derive calibration equation
•2nd sample – contains unknowns and is calibrated with
standards
•Advantage of External calibration – no risk of
concentration/dynamic range or ionization suppression
Reflector mode?
•Basically – it gives you better resolution
•Ion reflector – slows down incoming ions and reverses flight path
to detector
•This results in focusing the ion packets in space and time at the
detector.
Table 1. Measured mass-to-charge ratios (m/z), and proposed molecular species
associated with sphingolipids
*Ceramide monohexoside includes
glucosylceramide. "d" indicates
dihydroxy-sphingosine.
Conclusions
• Control patients produce sufficient lysosomal acid Bglucosidase and can properly hydrolyze CMH to ceramide,
which is a sphingomyelin precursor.
Lysosomal acid B-glucosidase
HYDROLYSIS
Ceramide monohexoside
Ceramide
Glucose
Sphingomyelin
• Normal ceramide monohexoside/sphingomyelin (CMH/SM) peak
intensity ratios circled in red.
Conclusions
Patients with Gaucher’s disease are deficient in lysosomal acid Bglucosidase and therefore cannot properly hydrolyze CMH to
ceramide, resulting in less sphingomyelin.
Lysosamal acid B-glucosidase
HYDROLYSIS
Ceramide monohexoside
Ceramide
Glucose
Sphingomyelin
• Ceramide monohexoside/sphingomyelin (CMH/SM) peak intensity
ratios are increased in different body fluids, circled in blue.