Introduction & Objective :

References:

From Achiral to Chircal Molecular Bis-Porphyrin Ladders

Karolina Parciak1, Ashley Delpeche1, Gloria Proni2, Ana G. Petrovic1

1 Department of Life Sciences, New York Institute of Technology, New York, NY, USA.

2 John Jay College of Criminal Justice, Science Department, New York, NY, USA.

• The double-strand helical structures are frequently found in nature and are closely related to the physiological

functions of biomolecules, such as nucleic acids (DNA, RNA, even PNA) and proteins.

• Although helical-induction of single-strand helices has been performed in the past, for example, by covalently

adhering enantiopure chiral additives to foldable polymers1,2, the induction of double-strand helices is rare.

• The Objective of the present research is to develop a novel,

sensitive tool for helical-sense programming

of double-stranded biomolecular architectures.

• The ability to induce supramolecular chirality and control the screw-sense and the degree of helicity plays a vital

role in the frontier of biomolecular recognition, material science and possibly information storage.

• The potential utilities of being able to reversibly transition from a ladder to a right- or left-handed helical-duplex

are:

a) in the field of binary bio-information storage (0,1), where a ladder could represent a molecular analogue of a

state “0” and helix could represent a molecular analogue of state “1”.

b) in development of a molecular gauge for double-stranded helix stability in biomolecular systems.

Specific Methodology :

Theoretical

Molecular

Mechanics

Methods

1. Building the ladders (6mer, 8mer, 10mer, 12mer, etc.), analogous ladders with porphyrins

and seeding the guest at various orientations;

2. Initial Minimization of host-guest ladders via Molecular Mechanics based, OPLS-2005

force-field, implicit H2O solvent model included;

3. Application of three Monte Carlo, Molecular Mechanics algorithms, OPLS-2005 force-

field;

4. Resorting to Single Point Energy calculation via Quantum Mechanics, DFT, 6-31G(TM)

basis set;

5. Determination of Bolzamann population for identified conformations (minimized

geometries).

Note: Molecular Modeling based simulations are accomplished via Schrodinger/Macro Model software,

while the Quantum Mechanical energy refinement will be accomplished via Schrodinger/Jaguar

software.

Monte Carlo Method: survey of potential energy surface via

random conformational changes in all bond exhibiting rotational

degrees of freedom.

• Two Zn-porphyrins are covalently attached to the scaffold of an achiral ladder-duplex.

• A small chiral guest is added in order to form a host/guest complex with the bis-porphyrins.

• The coordination between the nucleophilic groups of the chiral guest and Zn-centers of porphyris should induce a

helical-twist (stereo-differentiation) between the porphyrins, as similarly seen in the porphyrin-tweezer methodology3.

• As a result of stereo-differentiation, the two porphyrins should adopt a preferred chiral twist.

• The sign and the twist-sense should be governed by the Absolute Configuration of the chiral guest, while the extent

of stereo-differentiation (degree of twisting) via variation of the steric size of the guest (methyl vs. benzyl moieties).

General Methodology :

Zn+

Zn-porphyrin handle

Zn Zn

+

NH2 or OH NH2 or OH

chiral guest

Zn Zn

ZnZnZnZn

achiral ladder

achiral conjugate(host)

helical-sense induction and chirality propagation

guest coordination

NH2 or OH NH2 or OH

a) b) c) d)

Monte Carlo

(MC)

Algorithms

Monte Carlo Multiple Minimum (MCMM): torsional sampling which generates trial conformations by

randomly adjusting rotatable bonds.

Systematic Torsional Sampling (SPMC): method

employs a systematic search instead of a random search.

The search begins at low torsional resolution (120º), searches all

angles without duplicating coverage, then doubles the resolution.

Mixed Torsional/ Low mode sampling (MTLMS): combination of the random torsional changes with the low-mode

steps (explores the low-frequency eigenvectors of the system,

which are expected to follow “soft” degrees of freedom).

Gib

bs F

ree E

ne

rgy

RTEEii

ieN

NP

/)(

0

0

i

iP 1

Boltzmann Relation:

Summary & Future Outlook :

1. Yashima, E.; Katsuhiro, M. Macromolecules (Review). 2008, 41, 3–12.

2. Sanji, T.; Takase, K.; Sakuria, H. J. Am. Chem. Soc. 2001, 123, 12690–12691.

3. Berova, N.; Pescitelli, G.; Petrovic, A. G.; Proni, G. Chemical Communications. 2009,

5958-5980.

Ladder Candidates:

Synthetic Candidates for Ladder :

NH2

H2C

C

O

OH

NH2

CH2

CO

NH

CH2

CO

NH

CH2

CO

NH

CH2

CO

OH

N N

HOOC COOH H2C

HN

C O

H2C

HN

C O

H2C

HN

C O

H2C

H2N

CHO

O

X = 4 units

n

H2C

C

O

OHn

NH2

NH2

H2C

C

O

OHn

X = 6, 8, 10, 12, 16, 20 monomeric units

Monomeric Units:

Bridging Units: *

n = 1-3

OO

O

OHO

OH

O

OHO

OHH2C

1-2

a) b)

OO

OO

OO

Ladder examples:

OO

HO OH

HO

OO

OH

N N

R

R =H, Me, t-Bu

X = 6-20 monomeric units

Me

O

O NH

HN

NH2

Me

O

O

HO

OH

H2N NH2

HN

Me

O

O OH

O

O NH

HN

NH2

HN O

O OH

Me

Me

N N

+

• The methyl-based guest presents a smaller steric demand then the benzyl-based analogue, as evidenced by the extent of

inducted helical pitch;

• In order to impart a uniform double-stranded helical chirality, we came to understanding that the ladder has to exhibit a

dynamic balance of two factors:

a) sufficient flexibility for chirality to propagate from down the backbone of the ladder,

b) sufficient hydrogen bond reinforcement that keeps the two ladders from collapsing into a random-coil conformations;

• Right-handed helical induction has been observed for some of the investigated 6mers.

• We will continue to explore the most optimal length for helical chiral-induction;

• All molecular modeling geometries await single point energy evaluation based on QM to determine relative stability

between helical and random (collapsed) conformations;

further

subjected to

the MC search

Theoretical Methods and Data:

The preliminary Molecular Modeling Minimizations, carried-out till convergence

(no lower energy conformation obtained upon iterative minimization) provide insight

into propensity towards helical induction for the following two ladder-architectures:

&

NYIT travel grant

provided by Dean Yu

Acknowledgements:

Synthetic Scheme of First Ladder :

Chiral Guests

larger

benzyl-based guest

NNH

NH2

H O

smaller

methyl-based guest

NNH

NH2

H O

NH2

H2C

C

O

OH

NH2

CH2

CO

NH

CH2

CO

NH

CH2

CO

NH

CH2

CO

OH

N N

HOOC COOH H2C

HN

C O

H2C

HN

C O

H2C

HN

C O

H2C

H2N

CHO

O

X = 4 units

n

H2C

C

O

OHn

NH2

NH2

H2C

C

O

OHn

X = 6, 8, 10, 12, 16, 20 monomeric units

Monomeric Units:

Bridging Units: *

n = 1-3

OO

O

OHO

OH

O

OHO

OHH2C

1-2

a) b)

OO

OO

OO

Ladder examples:

OO

HO OH

HO

OO

OH

N N

R

R =H, Me, t-Bu

X = 6-20 monomeric units

Me

O

O NH

HN

NH2

Me

O

O

HO

OH

H2N NH2

HN

Me

O

O OH

O

O NH

HN

NH2

HN O

O OH

Me

Me

N N

+

n = 3

monomeric unit

of ladder scaffold

The selected Four Ladder Candidates:

monomeric unit

of ladder scaffold

H-bonding

bridging unit

+

NH2

H2C

C

O

OH

NH2

CH2

CO

NH

CH2

CO

NH

CH2

CO

NH

CH2

CO

OH

N N

HOOC COOH H2C

HN

C O

H2C

HN

C O

H2C

HN

C O

H2C

H2N

CHO

O

X = 4 units

n

H2C

C

O

OHn

NH2

NH2

H2C

C

O

OHn

X = 6, 8, 10, 12, 16, 20 monomeric units

Monomeric Units:

Bridging Units: *

n = 1-3

OO

O

OHO

OH

O

OHO

OHH2C

1-2

a) b)

OO

OO

OO

Ladder examples:

OO

HO OH

HO

OO

OH

N N

R

R =H, Me, t-Bu

X = 6-20 monomeric units

Me

O

O NH

HN

NH2

Me

O

O

HO

OH

H2N NH2

HN

Me

O

O OH

O

O NH

HN

NH2

HN O

O OH

Me

Me

N N

+

NH2

H2C

C

O

OH

NH2

CH2

CO

NH

CH2

CO

NH

CH2

CO

NH

CH2

CO

OH

N N

HOOC COOH H2C

HN

C O

H2C

HN

C O

H2C

HN

C O

H2C

H2N

CHO

O

X = 4 units

n

H2C

C

O

OHn

NH2

NH2

H2C

C

O

OHn

X = 6, 8, 10, 12, 16, 20 monomeric units

Monomeric Units:

Bridging Units: *

n = 1-3

OO

O

OHO

OH

O

OHO

OHH2C

1-2

a) b)

OO

OO

OO

Ladder examples:

OO

HO OH

HO

OO

OH

N N

R

R =H, Me, t-Bu

X = 6-20 monomeric units

Me

O

O NH

HN

NH2

Me

O

O

HO

OH

H2N NH2

HN

Me

O

O OH

O

O NH

HN

NH2

HN O

O OH

Me

Me

N N

+

n = 3 n = 2

n = 2

Seeded Host-Guest Complexes:

MCMM Monte Carlo Search resulted representative architectures, some of which are helical

benzyl-based guest methyl-based guest

NH2

H2C

C

O

OH

NH2

CH2

CO

NH

CH2

CO

NH

CH2

CO

NH

CH2

CO

OH

N N

HOOC COOH H2C

HN

C O

H2C

HN

C O

H2C

HN

C O

H2C

H2N

CHO

O

X = 4 units

n

H2C

C

O

OHn

NH2

NH2

H2C

C

O

OHn

X = 6, 8, 10, 12, 16, 20 monomeric units

Monomeric Units:

Bridging Units: *

n = 1-3

OO

O

OHO

OH

O

OHO

OHH2C

1-2

a) b)

OO

OO

OO

Ladder examples:

OO

HO OH

HO

OO

OH

N N

R

R =H, Me, t-Bu

X = 6-20 monomeric units

Me

O

O NH

HN

NH2

Me

O

O

HO

OH

H2N NH2

HN

Me

O

O OH

O

O NH

HN

NH2

HN O

O OH

Me

Me

N N

+

n = 2

Methyl-guest & L1

minimization no solvent

E= -4923.90kJ

Initial helical stride

D = - 6.7 deg

Methyl-guest & L1

minimization no solvent

E= -4861.409 kJ

Irregular helix

D = + 17.7 deg

Methyl-guest & L1

minimization no solvent

E= -4872.771 kJ

Irregular conformation

D = + 45.7 deg

Benzyl-guest & L1

minimization no solvent

E= -4877.032 kJ

Irregular helix

D = + 12.8 deg

Benzyl-guest & L1

minimization no solvent

E= -4788.264 kJ

Irregular conformation

D = + 12.7 deg

Benzyl-guest & L1

minimization no solvent

E= -5226.174kJ

Irregular conformation

D = + 10.6 deg

NH2

H2C

C

O

OH

NH2

CH2

CO

NH

CH2

CO

NH

CH2

CO

NH

CH2

CO

OH

N N

HOOC COOH H2C

HN

C O

H2C

HN

C O

H2C

HN

C O

H2C

H2N

CHO

O

X = 4 units

n

H2C

C

O

OHn

NH2

NH2

H2C

C

O

OHn

X = 6, 8, 10, 12, 16, 20 monomeric units

Monomeric Units:

Bridging Units: *

n = 1-3

OO

O

OHO

OH

O

OHO

OHH2C

1-2

a) b)

OO

OO

OO

Ladder examples:

OO

HO OH

HO

OO

OH

N N

R

R =H, Me, t-Bu

X = 6-20 monomeric units

Me

O

O NH

HN

NH2

Me

O

O

HO

OH

H2N NH2

HN

Me

O

O OH

O

O NH

HN

NH2

HN O

O OH

Me

Me

N N

+

n = 2

L1

L1B

L2

L2B